Lung Cancer Biomarkers and Uses Thereof

ABSTRACT

The present disclosure includes biomarkers, methods, devices, reagents, systems, and kits for the detection and diagnosis of non-small cell lung cancer and general cancer. In one aspect, methods are provided for diagnosing non-small cell lung cancer, where the methods include detecting, in a sample, at least one biomarker value corresponding to at least one biomarker selected from the biomarkers provided in Table 1, wherein an individual is classified as having lung cancer, or the likelihood of having lung cancer is determined, based on the at least one biomarker value. In another aspect, methods are provided for diagnosing cancer, where the methods include detecting, in a sample, at least one biomarker value corresponding to at least one biomarker selected from the biomarkers provided in Table 19, wherein an individual is classified as having cancer, or the likelihood of having cancer is determined, based on the at least one biomarker value.

RELATED APPLICATIONS

This application is a continuation in part of U.S. application Ser. No. 12/556,480, filed Sep. 9, 2009. This application also claims the benefit of U.S. Provisional Application Ser. No. 61/095,593, filed Sep. 9, 2008 and U.S. Provisional Application Ser. No. 61/152,837, filed Feb. 16, 2009. This application is also a continuation in part of International Application Serial No. PCT/US2011/043595, filed Jul. 11, 2011, which claims the benefit of U.S. Provisional Application Ser. No. 61/363,122, filed Jul. 9, 2010 and U.S. Provisional Application Ser. No. 61/444,947, filed Feb. 21, 2011. Each of these applications is incorporated herein by reference in its entirety for all purposes.

FIELD OF THE INVENTION

The present application relates generally to the detection of biomarkers and the diagnosis of cancer in an individual and, more specifically, to one or more biomarkers, methods, devices, reagents, systems, and kits for diagnosing cancer, more particularly lung cancer, in an individual.

BACKGROUND

The following description provides a summary of information relevant to the present application and is not an admission that any of the information provided or publications referenced herein is prior art to the present application.

More people die from lung cancer than any other type of cancer. This is true for both men and women. Lung cancer accounts for more deaths than breast cancer, prostate cancer, and colon cancer combined. Lung cancer accounted for an estimated 157,300 deaths, or 28% of all cancer deaths in the United States in 2010. It is estimated that in 2010, 116,750 men and 105,770 women will be diagnosed with lung cancer, and 86,220 men and 71,080 women will die from lung cancer (Jemal, C A Cancer J Clin 2010; 60:277). Among men in the United States, lung cancer is the second most common cancer among white, black, Asian/Pacific Islander, American Indian/Alaska Native, and Hispanic men. Among women in the United States, lung cancer is the second most common cancer among white, black, and American Indian/Alaska Native women, and the third most common cancer among Asian/Pacific Islander and Hispanic women. For those who do not quit smoking, the probability of death from lung cancer is 15% and remains above 5% even for those who quit at age 50-59. The annual healthcare cost of lung cancer in the U.S. alone is $95 billion.

Ninety-one percent of lung cancer caused by smoking is non-small cell lung cancer (NSCLC), which represents approximately 85% of all lung cancers. The remaining 15% of all lung cancers are small cell lung cancers, although mixed-cell lung cancers do occur. Because small cell lung cancer is rare and rapidly fatal, the opportunity for early detection is small.

There are three main types of NSCLC: squamous cell carcinoma, large cell carcinoma, and adenocarcinoma. Adenocarcinoma is the most common form of lung cancer (30%-65%) and is the lung cancer most frequently found in both smokers and non-smokers. Squamous cell carcinoma accounts for 25-30% of all lung cancers and is generally found in a proximal bronchus. Early stage NSCLC tends to be localized, and if detected early it can often be treated by surgery with a favorable outcome and improved survival. Other treatment options include radiation treatment, drug therapy, and a combination of these methods.

NSCLC is staged by the size of the tumor and its presence in other tissues including lymph nodes. In the occult stage, cancer cells may be found in sputum samples or lavage samples and no tumor is detectable in the lungs. In stage 0, only the innermost lining of the lungs exhibit cancer cells and the tumor has not grown through the lining. In stage IA, the cancer is considered locally invasive and has grown deep into the lung tissue but the tumor is less than 3 cm across. In this stage, the tumor is not found in the main bronchus or lymph nodes. In stage IB, the tumor is either larger than 3 cm across or has grown into the bronchus or pleura, but has not grown into the lymph nodes. In stage IIA, the tumor is less than 7 cm across and may have grown into the lymph nodes. In stage IIB, the tumor has either been found in the lymph nodes and is greater than 5 cm across or grown into the bronchus or pleura; or the cancer is not in the lymph nodes but is found in the chest wall, diaphragm, pleura, bronchus, or tissue that surrounds the heart, or separate tumor nodules are present in the same lobe of the lung. In stage IIIA, cancer cells are found in the lymph nodes near the lung and bronchi and in those between the lungs but on the side of the chest where the tumor is located. Stage IIIB, cancer cells are located on the opposite side of the chest from the tumor or in the neck. Other organs near the lungs may also have cancer cells and multiple tumors may be found in one lobe of the lungs. In stage IV, tumors are found in more than one lobe of the same lung or both lungs and cancer cells are found in other parts of the body.

Current methods of diagnosis for lung cancer include testing sputum for cancerous cells, chest x-ray, fiber optic evaluation and biopsy of airways, and low dose spiral computed tomography (CT). Sputum cytology has a very low sensitivity. Chest X-ray is also relatively insensitive, requiring lesions to be greater than 1 cm in size to be visible. Bronchoscopy requires that the tumor is visible inside airways accessible to the bronchoscope. The most widely recognized diagnostic method is low dose chest CT, but in common with X-ray, the use of CT involves ionizing radiation, which itself can cause cancer. CT also has significant limitations: the scans require a high level of technical skill to interpret and many of the observed abnormalities are not in fact lung cancer and substantial healthcare costs are incurred in following up CT findings. The most common incidental finding is a benign lung nodule.

Lung nodules are relatively round lesions, or areas of abnormal tissue, located within the lung and may vary in size. Lung nodules may be benign or cancerous, but most are benign. If a nodule is below 4 mm the prevalence is only 1.5%, if 4-8 mm the prevalence is approximately 6%, and if above 20 mm the incidence is approximately 20%. For small and medium-sized nodules, the patient is advised to undergo a repeat scan within three months to a year. For many large nodules, the patient receives a biopsy (which is invasive and may lead to complications) even though most of these are benign.

Therefore, diagnostic methods that can replace or complement CT are needed to reduce the number of surgical procedures conducted and minimize the risk of surgical complications. In addition, even when lung nodules are absent or unknown, methods are needed to detect lung cancer at its early stages to improve patient outcomes. Only 16% of lung cancer cases are diagnosed as localized, early stage cancer, where the 5-year survival rate is 46%, compared to 84% of those diagnosed at late stage, where the 5-year survival rate is only 13%. This demonstrates that relying on symptoms for diagnosis is not useful because many of them are common to other lung diseases and often present only in the later stages of lung cancer. These symptoms include a persistent cough, bloody sputum, chest pain, and recurring bronchitis or pneumonia.

Where methods of early diagnosis in cancer exist, the benefits are generally accepted by the medical community. Cancers that have widely utilized screening protocols have the highest 5-year survival rates, such as breast cancer (88%) and colon cancer (65%) versus 16% for lung cancer. However, up to 88% of lung cancer patients survive ten years or longer if the cancer is diagnosed at Stage I through screening. This demonstrates the clear need for diagnostic methods that can reliably detect early-stage NSCLC.

Biomarker selection for a specific disease state involves first the identification of markers that have a measurable and statistically significant difference in a disease population compared to a control population for a specific medical application. Biomarkers can include secreted or shed molecules that parallel disease development or progression and readily diffuse into the blood stream from lung tissue or from distal tissues in response to a lesion. They may also include proteins made by cells in response to the tumor. The biomarker or set of biomarkers identified are generally clinically validated or shown to be a reliable indicator for the original intended use for which it was selected. Biomarkers can include small molecules, metabolites, peptides, proteins, and nucleic acids. Some of the key issues that affect the identification of biomarkers include over-fitting of the available data and bias in the data.

A variety of methods have been utilized in an attempt to identify biomarkers and diagnose disease. For protein-based markers, these include two-dimensional electrophoresis, mass spectrometry, and immunoassay methods. For nucleic acid markers, these include mRNA expression profiles, microRNA profiles, FISH, serial analysis of gene expression (SAGE), and large scale gene expression arrays.

The utility of two-dimensional electrophoresis is limited by low detection sensitivity; issues with protein solubility, charge, and hydrophobicity; gel reproducibility; and the possibility of a single spot representing multiple proteins. For mass spectrometry, depending on the format used, limitations revolve around the sample processing and separation, sensitivity to low abundance proteins, signal to noise considerations, and inability to immediately identify the detected protein. Limitations in immunoassay approaches to biomarker discovery are centered on the inability of antibody-based multiplex assays to measure a large number of analytes. One might simply print an array of high-quality antibodies and, without sandwiches, measure the analytes bound to those antibodies. (This would be the formal equivalent of using a whole genome of nucleic acid sequences to measure by hybridization all DNA or RNA sequences in an organism or a cell. The hybridization experiment works because hybridization can be a stringent test for identity. Even very good antibodies are not stringent enough in selecting their binding partners to work in the context of blood or even cell extracts because the protein ensemble in those matrices have extremely different abundances.) Thus, one must use a different approach with immunoassay-based approaches to biomarker discovery one would need to use multiplexed ELISA assays (that is, sandwiches) to get sufficient stringency to measure many analytes simultaneously to decide which analytes are indeed biomarkers. Sandwich immunoassays do not scale to high content, and thus biomarker discovery using stringent sandwich immunoassays is not possible using standard array formats. Lastly, antibody reagents are subject to substantial lot variability and reagent instability. The instant platform for protein biomarker discovery overcomes this problem.

Many of these methods rely on or require some type of sample fractionation prior to the analysis. Thus the sample preparation required to run a sufficiently powered study designed to identify/discover statistically relevant biomarkers in a series of well-defined sample populations is extremely difficult, costly, and time consuming. During fractionation, a wide range of variability can be introduced into the various samples. For example, a potential marker could be unstable to the process, the concentration of the marker could be changed, inappropriate aggregation or disaggregation could occur, and inadvertent sample contamination could occur and thus obscure the subtle changes anticipated in early disease.

It is widely accepted that biomarker discovery and detection methods using these technologies have serious limitations for the identification of diagnostic biomarkers. These limitations include an inability to detect low-abundance biomarkers, an inability to consistently cover the entire dynamic range of the proteome, irreproducibility in sample processing and fractionation, and overall irreproducibility and lack of robustness of the method. Further, these studies have introduced biases into the data and not adequately addressed the complexity of the sample populations, including appropriate controls, in terms of the distribution and randomization required to identify and validate biomarkers within a target disease population.

Although efforts aimed at the discovery of new and effective biomarkers have gone on for several decades, the efforts have been largely unsuccessful. Biomarkers for various diseases typically have been identified in academic laboratories, usually through an accidental discovery while doing basic research on some disease process. Based on the discovery and with small amounts of clinical data, papers were published that suggested the identification of a new biomarker. Most of these proposed biomarkers, however, have not been confirmed as real or useful biomarkers, primarily because the small number of clinical samples tested provide only weak statistical proof that an effective biomarker has in fact been found. That is, the initial identification was not rigorous with respect to the basic elements of statistics. In each of the years 1994 through 2003, a search of the scientific literature shows that thousands of references directed to biomarkers were published. During that same time frame, however, the FDA approved for diagnostic use, at most, three new protein biomarkers a year, and in several years no new protein biomarkers were approved.

Based on the history of failed biomarker discovery efforts, mathematical theories have been proposed that further promote the general understanding that biomarkers for disease are rare and difficult to find. Biomarker research based on 2D gels or mass spectrometry supports these notions. Very few useful biomarkers have been identified through these approaches. However, it is usually overlooked that 2D gel and mass spectrometry measure proteins that are present in blood at approximately 1 nM concentrations and higher, and that this ensemble of proteins may well be the least likely to change with disease. Other than the instant biomarker discovery platform, proteomic biomarker discovery platforms that are able to accurately measure protein expression levels at much lower concentrations do not exist.

Much is known about biochemical pathways for complex human biology. Many biochemical pathways culminate in or are started by secreted proteins that work locally within the pathology, for example growth factors are secreted to stimulate the replication of other cells in the pathology, and other factors are secreted to ward off the immune system, and so on. While many of these secreted proteins work in a paracrine fashion, some operate distally in the body. One skilled in the art with a basic understanding of biochemical pathways would understand that many pathology-specific proteins ought to exist in blood at concentrations below (even far below) the detection limits of 2D gels and mass spectrometry. What must precede the identification of this relatively abundant number of disease biomarkers is a proteomic platform that can analyze proteins at concentrations below those detectable by 2D gels or mass spectrometry.

Accordingly, a need exists for biomarkers, methods, devices, reagents, systems, and kits that enable (a) screening high risk smokers for lung cancer (b) the differentiation of benign pulmonary nodules from malignant pulmonary nodules; (c) the detection of lung cancer biomarkers; and (d) the diagnosis of lung cancer.

SUMMARY

The present application includes biomarkers, methods, reagents, devices, systems, and kits for the detection and diagnosis of cancer and more particularly, NSCLC. The biomarkers of the present application were identified using a multiplex aptamer-based assay which is described in detail in Example 1. By using the aptamer-based biomarker identification method described herein, this application describes a surprisingly large number of NSCLC biomarkers that are useful for the detection and diagnosis of NSCLC as well as a large number of cancer biomarkers that are useful for the detection and diagnosis of cancer more generally. In identifying these biomarkers, over 1000 proteins from hundreds of individual samples were measured, some of which were at concentrations in the low femtomolar range. This is about four orders of magnitude lower than biomarker discovery experiments done with 2D gels and/or mass spectrometry.

While certain of the described NSCLC biomarkers are useful alone for detecting and diagnosing NSCLC, methods are described herein for the grouping of multiple subsets of the NSCLC biomarkers that are useful as a panel of biomarkers. Once an individual biomarker or subset of biomarkers has been identified, the detection or diagnosis of NSCLC in an individual can be accomplished using any assay platform or format that is capable of measuring differences in the levels of the selected biomarker or biomarkers in a biological sample.

However, it was only by using the aptamer-based biomarker identification method described herein, wherein over 1000 separate potential biomarker values were individually screened from a large number of individuals having previously been diagnosed either as having or not having NSCLC that it was possible to identify the NSCLC biomarkers disclosed herein. This discovery approach is in stark contrast to biomarker discovery from conditioned media or lysed cells as it queries a more patient-relevant system that requires no translation to human pathology.

Thus, in one aspect of the instant application, one or more biomarkers are provided for use either alone or in various combinations to diagnose NSCLC or permit the differential diagnosis of NSCLC from benign conditions such as those found in individuals with indeterminate pulmonary nodules identified with a CT scan or other imaging method, screening of high risk smokers for NSCLC, and diagnosing an individual with NSCLC. Exemplary embodiments include the biomarkers provided in Table 1, which as noted above, were identified using a multiplex aptamer-based assay, as described generally in Example 1 and more specifically in Example 2 and 5. The markers provided in Table 1 are useful in diagnosing NSCLC in a high risk population and for distinguishing benign pulmonary diseases in individuals with indeterminate pulmonary nodules from NSCLC.

While certain of the described NSCLC biomarkers are useful alone for detecting and diagnosing NSCLC, methods are also described herein for the grouping of multiple subsets of the NSCLC biomarkers that are each useful as a panel of two or more biomarkers. Thus, various embodiments of the instant application provide combinations comprising N biomarkers, wherein N is at least two biomarkers. In other embodiments, N is selected to be any number from 2-59 biomarkers.

In yet other embodiments, N is selected to be any number from 2-5, 2-10, 2-15, 2-20, 2-25, 2-30, 2-35, 2-40, 2-45, 2-50, 2-55, or 2-59. In other embodiments, N is selected to be any number from 3-5, 3-10, 3-15, 3-20, 3-25, 3-30, 3-35, 3-40, 3-45, 3-50, 3-55, or 3-59. In other embodiments, N is selected to be any number from 4-5, 4-10, 4-15, 4-20, 4-25, 4-30, 4-35, 4-40, 4-45, 4-50, 4-55, or 4-59. In other embodiments, N is selected to be any number from 5-10, 5-15, 5-20, 5-25, 5-30, 5-35, 5-40, 5-45, 5-50, 5-55, or 5-59. In other embodiments, N is selected to be any number from 6-10, 6-15, 6-20, 6-25, 6-30, 6-35, 6-40, 6-45, 6-50, 6-55, or 6-59. In other embodiments, N is selected to be any number from 7-10, 7-15, 7-20, 7-25, 7-30, 7-35, 7-40, 7-45, 7-50, 7-55, or 7-59. In other embodiments, N is selected to be any number from 8-10, 8-15, 8-20, 8-25, 8-30, 8-35, 8-40, 8-45, 8-50, 8-55, or 8-59. In other embodiments, N is selected to be any number from 9-10, 9-15, 9-20, 9-25, 9-30, 9-35, 9-40, 9-45, 9-50, 9-55, or 9-59. In other embodiments, N is selected to be any number from 10-15, 10-20, 10-25, 10-30, 10-35, 10-40, 10-45, 10-50, 10-55, or 10-59. It will be appreciated that N can be selected to encompass similar, but higher order, ranges.

In another aspect, a method is provided for diagnosing NSCLC in an individual, the method including detecting, in a biological sample from an individual, at least one biomarker value corresponding to at least one biomarker selected from the group of biomarkers provided in Table 1, wherein the individual is classified as having NSCLC based on the at least one biomarker value.

In another aspect, a method is provided for diagnosing NSCLC in an individual, the method including detecting, in a biological sample from an individual, biomarker values that each correspond to one of at least N biomarkers selected from the group of biomarkers set forth in Table 1, wherein the likelihood of the individual having NSCLC is determined based on the biomarker values.

In another aspect, a method is provided for diagnosing NSCLC in an individual, the method including detecting, in a biological sample from an individual, biomarker values that each correspond to one of at least N biomarkers selected from the group of biomarkers set forth in Table 1, wherein the individual is classified as having NSCLC based on the biomarker values, and wherein N=2-10.

In another aspect, a method is provided for diagnosing NSCLC in an individual, the method including detecting, in a biological sample from an individual, biomarker values that each correspond to one of at least N biomarkers selected from the group of biomarkers set forth in Table 1, wherein the likelihood of the individual having NSCLC is determined based on the biomarker values, and wherein N=2-10.

In another aspect, a method is provided for diagnosing that an individual does not have NSCLC, the method including detecting, in a biological sample from an individual, at least one biomarker value corresponding to at least one biomarker selected from the group of biomarkers set forth in Table 1, wherein the individual is classified as not having NSCLC based on the at least one biomarker value.

In another aspect, a method is provided for diagnosing that an individual does not have NSCLC, the method including detecting, in a biological sample from an individual, biomarker values that each corresponding to one of at least N biomarkers selected from the group of biomarkers set forth in Table 1, wherein the individual is classified as not having NSCLC based on the biomarker values, and wherein N=2-10.

In another aspect, a method is provided for diagnosing NSCLC, the method including detecting, in a biological sample from an individual, biomarker values that each correspond to a biomarker on a panel of N biomarkers, wherein the biomarkers are selected from the group of biomarkers set forth in Table 1, wherein a classification of the biomarker values indicates that the individual has NSCLC, and wherein N=3-10.

In another aspect, a method is provided for diagnosing NSCLC, the method including detecting, in a biological sample from an individual, biomarker values that each correspond to a biomarker on a panel of biomarkers selected from the group of panels set forth in Tables 2-11, wherein a classification of the biomarker values indicates that the individual has NSCLC.

In another aspect, a method is provided for diagnosing an absence of NSCLC, the method including detecting, in a biological sample from an individual, biomarker values that each correspond to a biomarker on a panel of N biomarkers, wherein the biomarkers are selected from the group of biomarkers set forth in Table 1, wherein a classification of the biomarker values indicates an absence of NSCLC in the individual, and wherein N=3-10.

In another aspect, a method is provided for diagnosing an absence of NSCLC, the method including detecting, in a biological sample from an individual, biomarker values that each correspond to a biomarker on a panel of N biomarkers, wherein the biomarkers are selected from the group of biomarkers set forth in Table 1, wherein a classification of the biomarker values indicates an absence of NSCLC in the individual, and wherein N=3-10.

In another aspect, a method is provided for diagnosing an absence of NSCLC, the method including detecting, in a biological sample from an individual, biomarker values that each correspond to a biomarker on a panel of biomarkers selected from the group of panels provided in Tables 2-11, wherein a classification of the biomarker values indicates an absence of NSCLC in the individual.

In another aspect, a method is provided for diagnosing NSCLC in an individual, the method including detecting, in a biological sample from an individual, biomarker values that correspond to one of at least N biomarkers selected from the group of biomarkers set forth in Table 1, wherein the individual is classified as having NSCLC based on a classification score that deviates from a predetermined threshold, and wherein N=2-10.

In another aspect, a method is provided for diagnosing an absence of NSCLC in an individual, the method including detecting, in a biological sample from an individual, biomarker values that correspond to one of at least N biomarkers selected from the group of biomarkers set forth in Table 1, wherein said individual is classified as not having NSCLC based on a classification score that deviates from a predetermined threshold, and wherein N=2-10.

In another aspect, a computer-implemented method is provided for indicating a likelihood of NSCLC. The method comprises: retrieving on a computer biomarker information for an individual, wherein the biomarker information comprises biomarker values that each correspond to one of at least N biomarkers, wherein N is as defined above, selected from the group of biomarkers set forth in Table 1; performing with the computer a classification of each of the biomarker values; and indicating a likelihood that the individual has NSCLC based upon a plurality of classifications.

In another aspect, a computer-implemented method is provided for classifying an individual as either having or not having NSCLC. The method comprises: retrieving on a computer biomarker information for an individual, wherein the biomarker information comprises biomarker values that each correspond to one of at least N biomarkers selected from the group of biomarkers provided in Table 1; performing with the computer a classification of each of the biomarker values; and indicating whether the individual has NSCLC based upon a plurality of classifications.

In another aspect, a computer program product is provided for indicating a likelihood of NSCLC. The computer program product includes a computer readable medium embodying program code executable by a processor of a computing device or system, the program code comprising: code that retrieves data attributed to a biological sample from an individual, wherein the data comprises biomarker values that each correspond to one of at least N biomarkers, wherein N is as defined above, in the biological sample selected from the group of biomarkers set forth in Table 1; and code that executes a classification method that indicates a likelihood that the individual has NSCLC as a function of the biomarker values.

In another aspect, a computer program product is provided for indicating a NSCLC status of an individual. The computer program product includes a computer readable medium embodying program code executable by a processor of a computing device or system, the program code comprising: code that retrieves data attributed to a biological sample from an individual, wherein the data comprises biomarker values that each correspond to one of at least N biomarkers in the biological sample selected from the group of biomarkers provided in Table 1; and code that executes a classification method that indicates a NSCLC status of the individual as a function of the biomarker values.

In another aspect, a computer-implemented method is provided for indicating a likelihood of NSCLC. The method comprises retrieving on a computer biomarker information for an individual, wherein the biomarker information comprises a biomarker value corresponding to a biomarker selected from the group of biomarkers set forth in Table 1; performing with the computer a classification of the biomarker value; and indicating a likelihood that the individual has NSCLC based upon the classification.

In another aspect, a computer-implemented method is provided for classifying an individual as either having or not having NSCLC. The method comprises retrieving from a computer biomarker information for an individual, wherein the biomarker information comprises a biomarker value corresponding to a biomarker selected from the group of biomarkers provided in Table 1; performing with the computer a classification of the biomarker value; and indicating whether the individual has NSCLC based upon the classification.

In still another aspect, a computer program product is provided for indicating a likelihood of NSCLC. The computer program product includes a computer readable medium embodying program code executable by a processor of a computing device or system, the program code comprising: code that retrieves data attributed to a biological sample from an individual, wherein the data comprises a biomarker value corresponding to a biomarker in the biological sample selected from the group of biomarkers set forth in Table 1; and code that executes a classification method that indicates a likelihood that the individual has NSCLC as a function of the biomarker value.

In still another aspect, a computer program product is provided for indicating a NSCLC status of an individual. The computer program product includes a computer readable medium embodying program code executable by a processor of a computing device or system, the program code comprising: code that retrieves data attributed to a biological sample from an individual, wherein the data comprises a biomarker value corresponding to a biomarker in the biological sample selected from the group of biomarkers provided in Table 1; and code that executes a classification method that indicates a NSCLC status of the individual as a function of the biomarker value.

While certain of the described biomarkers are also useful alone for detecting and diagnosing general cancer, methods are described herein for the grouping of multiple subsets of the biomarkers that are useful as a panel of biomarkers for detecting and diagnosing cancer in general. Once an individual biomarker or subset of biomarkers has been identified, the detection or diagnosis of cancer in an individual can be accomplished using any assay platform or format that is capable of measuring differences in the levels of the selected biomarker or biomarkers in a biological sample.

However, it was only by using the aptamer-based biomarker identification method described herein, wherein over 1000 separate potential biomarker values were individually screened from a large number of individuals having previously been diagnosed either as having or not having cancer that it was possible to identify the cancer biomarkers disclosed herein. This discovery approach is in stark contrast to biomarker discovery from conditioned media or lysed cells as it queries a more patient-relevant system that requires no translation to human pathology.

Thus, in one aspect of the instant application, one or more biomarkers are provided for use either alone or in various combinations to diagnose cancer. Exemplary embodiments include the biomarkers provided in Table 19, which were identified using a multiplex aptamer-based assay, as described generally in Example 1 and more specifically in Example 6. The markers provided in Table 19 are useful in distinguishing individuals who have cancer from those who do not have cancer.

While certain of the described cancer biomarkers are useful alone for detecting and diagnosing cancer, methods are also described herein for the grouping of multiple subsets of the cancer biomarkers that are each useful as a panel of three or more biomarkers. Thus, various embodiments of the instant application provide combinations comprising N biomarkers, wherein N is at least three biomarkers. In other embodiments, N is selected to be any number from 3-23 biomarkers.

In yet other embodiments, N is selected to be any number from 2-5, 2-10, 2-15, 2-20, or 2-23. In other embodiments, N is selected to be any number from 3-5, 3-10, 3-15, 3-20, or 3-23. In other embodiments, N is selected to be any number from 4-5, 4-10, 4-15, 4-20, or 4-23. In other embodiments, N is selected to be any number from 5-10, 5-15, 5-20, or 5-23. In other embodiments, N is selected to be any number from 6-10, 6-15, 6-20, or 6-23. In other embodiments, N is selected to be any number from 7-10, 7-15, 7-20, or 7-23. In other embodiments, N is selected to be any number from 8-10, 8-15, 8-20, or 8-23. In other embodiments, N is selected to be any number from 9-10, 9-15, 9-20, or 9-23. In other embodiments, N is selected to be any number from 10-15, 10-20, or 10-23. It will be appreciated that N can be selected to encompass similar, but higher order, ranges.

In another aspect, a method is provided for diagnosing cancer in an individual, the method including detecting, in a biological sample from an individual, at least one biomarker value corresponding to at least one biomarker selected from the group of biomarkers provided in Table 19, wherein the individual is classified as having cancer based on the at least one biomarker value.

In another aspect, a method is provided for diagnosing cancer in an individual, the method including detecting, in a biological sample from an individual, biomarker values that each correspond to one of at least N biomarkers selected from the group of biomarkers set forth in Table 19, wherein the likelihood of the individual having cancer is determined based on the biomarker values.

In another aspect, a method is provided for diagnosing cancer in an individual, the method including detecting, in a biological sample from an individual, biomarker values that each correspond to one of at least N biomarkers selected from the group of biomarkers set forth in Table 19, wherein the individual is classified as having cancer based on the biomarker values, and wherein N=3-10.

In another aspect, a method is provided for diagnosing cancer in an individual, the method including detecting, in a biological sample from an individual, biomarker values that each correspond to one of at least N biomarkers selected from the group of biomarkers set forth in Table 19, wherein the likelihood of the individual having cancer is determined based on the biomarker values, and wherein N=3-10.

In another aspect, a method is provided for diagnosing that an individual does not have cancer, the method including detecting, in a biological sample from an individual, at least one biomarker value corresponding to at least one biomarker selected from the group of biomarkers set forth in Table 19, wherein the individual is classified as not having cancer based on the at least one biomarker value.

In another aspect, a method is provided for diagnosing that an individual does not have cancer, the method including detecting, in a biological sample from an individual, biomarker values that each corresponding to one of at least N biomarkers selected from the group of biomarkers set forth in Table 19, wherein the individual is classified as not having cancer based on the biomarker values, and wherein N=3-10.

In another aspect, a method is provided for diagnosing cancer, the method including detecting, in a biological sample from an individual, biomarker values that each correspond to a biomarker on a panel of N biomarkers, wherein the biomarkers are selected from the group of biomarkers set forth in Table 19, wherein a classification of the biomarker values indicates that the individual has cancer, and wherein N=3-10.

In another aspect, a method is provided for diagnosing cancer, the method including detecting, in a biological sample from an individual, biomarker values that each correspond to a biomarker on a panel of biomarkers selected from the group of panels set forth in Tables 20-29 wherein a classification of the biomarker values indicates that the individual has cancer.

In another aspect, a method is provided for diagnosing an absence of cancer, the method including detecting, in a biological sample from an individual, biomarker values that each correspond to a biomarker on a panel of N biomarkers, wherein the biomarkers are selected from the group of biomarkers set forth in Table 19, wherein a classification of the biomarker values indicates an absence of cancer in the individual, and wherein N=3-10.

In another aspect, a method is provided for diagnosing an absence of cancer, the method including detecting, in a biological sample from an individual, biomarker values that each correspond to a biomarker on a panel of biomarkers selected from the group of panels provided in Tables 20-29, wherein a classification of the biomarker values indicates an absence of cancer in the individual.

In another aspect, a method is provided for diagnosing cancer in an individual, the method including detecting, in a biological sample from an individual, biomarker values that correspond to one of at least N biomarkers selected from the group of biomarkers set forth in Table 19, wherein the individual is classified as having cancer based on a classification score that deviates from a predetermined threshold, and wherein N=3-10.

In another aspect, a method is provided for diagnosing an absence of cancer in an individual, the method including detecting, in a biological sample from an individual, biomarker values that correspond to one of at least N biomarkers selected from the group of biomarkers set forth in Table 19, wherein said individual is classified as not having cancer based on a classification score that deviates from a predetermined threshold, and wherein N=3-10.

In another aspect, a computer-implemented method is provided for indicating a likelihood of cancer. The method comprises: retrieving on a computer biomarker information for an individual, wherein the biomarker information comprises biomarker values that each correspond to one of at least N biomarkers, wherein N is as defined above, selected from the group of biomarkers set forth in Table 19; performing with the computer a classification of each of the biomarker values; and indicating a likelihood that the individual has cancer based upon a plurality of classifications.

In another aspect, a computer-implemented method is provided for classifying an individual as either having or not having cancer. The method comprises: retrieving on a computer biomarker information for an individual, wherein the biomarker information comprises biomarker values that each correspond to one of at least N biomarkers selected from the group of biomarkers provided in Table 19; performing with the computer a classification of each of the biomarker values; and indicating whether the individual has cancer based upon a plurality of classifications.

In another aspect, a computer program product is provided for indicating a likelihood of cancer. The computer program product includes a computer readable medium embodying program code executable by a processor of a computing device or system, the program code comprising: code that retrieves data attributed to a biological sample from an individual, wherein the data comprises biomarker values that each correspond to one of at least N biomarkers, wherein N is as defined above, in the biological sample selected from the group of biomarkers set forth in Table 19; and code that executes a classification method that indicates a likelihood that the individual has cancer as a function of the biomarker values.

In another aspect, a computer program product is provided for indicating a cancer status of an individual. The computer program product includes a computer readable medium embodying program code executable by a processor of a computing device or system, the program code comprising: code that retrieves data attributed to a biological sample from an individual, wherein the data comprises biomarker values that each correspond to one of at least N biomarkers in the biological sample selected from the group of biomarkers provided in Table 19; and code that executes a classification method that indicates a cancer status of the individual as a function of the biomarker values.

In another aspect, a computer-implemented method is provided for indicating a likelihood of cancer. The method comprises retrieving on a computer biomarker information for an individual, wherein the biomarker information comprises a biomarker value corresponding to a biomarker selected from the group of biomarkers set forth in Table 19; performing with the computer a classification of the biomarker value; and indicating a likelihood that the individual has cancer based upon the classification.

In another aspect, a computer-implemented method is provided for classifying an individual as either having or not having cancer. The method comprises retrieving from a computer biomarker information for an individual, wherein the biomarker information comprises a biomarker value corresponding to a biomarker selected from the group of biomarkers provided in Table 19; performing with the computer a classification of the biomarker value; and indicating whether the individual has cancer based upon the classification.

In still another aspect, a computer program product is provided for indicating a likelihood of cancer. The computer program product includes a computer readable medium embodying program code executable by a processor of a computing device or system, the program code comprising: code that retrieves data attributed to a biological sample from an individual, wherein the data comprises a biomarker value corresponding to a biomarker in the biological sample selected from the group of biomarkers set forth in Table 19; and code that executes a classification method that indicates a likelihood that the individual has cancer as a function of the biomarker value.

In still another aspect, a computer program product is provided for indicating a cancer status of an individual. The computer program product includes a computer readable medium embodying program code executable by a processor of a computing device or system, the program code comprising: code that retrieves data attributed to a biological sample from an individual, wherein the data comprises a biomarker value corresponding to a biomarker in the biological sample selected from the group of biomarkers provided in Table 19; and code that executes a classification method that indicates a cancer status of the individual as a function of the biomarker value.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1A is a flowchart for an exemplary method for detecting NSCLC in a biological sample.

FIG. 1B is a flowchart for an exemplary method for detecting NSCLC in a biological sample using a naïve Bayes classification method.

FIG. 2 shows a ROC curve for a single biomarker, MMP7, using a naïve Bayes classifier for a test that detects NSCLC.

FIG. 3 shows ROC curves for biomarker panels of from two to ten biomarkers using naïve Bayes classifiers for a test that detects NSCLC.

FIG. 4 illustrates the increase in the classification score (AUC) as the number of biomarkers is increased from one to ten using naïve Bayes classification for a NSCLC panel.

FIG. 5 shows the measured biomarker distributions for MMP7 as a cumulative distribution function (cdf) in log-transformed RFU for the smokers and benign pulmonary nodules controls combined (solid line) and the NSCLC disease group (dotted line) along with their curve fits to a normal cdf (dashed lines) used to train the naïve Bayes classifiers.

FIG. 6 illustrates an exemplary computer system for use with various computer-implemented methods described herein.

FIG. 7 is a flowchart for a method of indicating the likelihood that an individual has NSCLC in accordance with one embodiment.

FIG. 8 is a flowchart for a method of indicating the likelihood that an individual has NSCLC in accordance with one embodiment.

FIG. 9 illustrates an exemplary aptamer assay that can be used to detect one or more NSCLC biomarkers in a biological sample.

FIG. 10 shows a histogram of frequencies for which biomarkers were used in building classifiers to distinguish between NSCLC and the smokers and benign pulmonary nodules control group from an aggregated set of potential biomarkers.

FIG. 11A shows a pair of histograms summarizing all possible single protein naïve Bayes classifier scores (AUC) using the biomarkers set forth in Table 1 (black) and a set of random markers (grey).

FIG. 11B shows a pair of histograms summarizing all possible two-protein protein naïve Bayes classifier scores (AUC) using the biomarkers set forth in Table 1 (black) and a set of random markers (grey).

FIG. 11C shows a pair of histograms summarizing all possible three-protein naïve Bayes classifier scores (AUC) using the biomarkers set forth in Table 1 (black) and a set of random markers (grey).

FIG. 12 shows the AUC for naïve Bayes classifiers using from 2-10 markers selected from the full panel and the scores obtained by dropping the best 5, 10, and 15 markers during classifier generation.

FIG. 13A shows a set of ROC curves modeled from the data in Table 14 for panels of from two to five markers.

FIG. 13B shows a set of ROC curves computed from the training data for panels of from two to five markers as in FIG. 12A.

FIG. 14 shows a ROC curve computed from the clinical biomarker panel described in Example 5.

FIGS. 15A and 15B show a comparison of performance between ten cancer biomarkers selected by a greedy selection procedure described in Example 6 (Table 19) and 1,000 randomly sampled sets of ten “non marker” biomarkers. The mean AUC for the ten cancer biomarkers in Table 19 is shown as a dotted vertical line. In FIG. 15A, sets of ten “nonmarkers” were randomly selected that were not selected by the greedy procedure described in Example 6. In FIG. 15B, the same procedure as 15A was used; however, the sampling was restricted to the remaining 49 NSCLC biomarkers from Table 1 that were not selected by the greedy procedure described in Example 6.

FIG. 16 shows receiver operating characteristic (ROC) curves for the 3 naïve Bayes classifiers set forth in Table 31. For each study, the area under the curve (AUC) is also displayed next to the legend.

DETAILED DESCRIPTION

Reference will now be made in detail to representative embodiments of the invention. While the invention will be described in conjunction with the enumerated embodiments, it will be understood that the invention is not intended to be limited to those embodiments. On the contrary, the invention is intended to cover all alternatives, modifications, and equivalents that may be included within the scope of the present invention as defined by the claims.

One skilled in the art will recognize many methods and materials similar or equivalent to those described herein, which could be used in and are within the scope of the practice of the present invention. The present invention is in no way limited to the methods and materials described.

Unless defined otherwise, technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Although any methods, devices, and materials similar or equivalent to those described herein can be used in the practice or testing of the invention, the preferred methods, devices and materials are now described.

All publications, published patent documents, and patent applications cited in this application are indicative of the level of skill in the art(s) to which the application pertains. All publications, published patent documents, and patent applications cited herein are hereby incorporated by reference to the same extent as though each individual publication, published patent document, or patent application was specifically and individually indicated as being incorporated by reference.

As used in this application, including the appended claims, the singular forms “a,” “an,” and “the” include plural references, unless the content clearly dictates otherwise, and are used interchangeably with “at least one” and “one or more.” Thus, reference to “an aptamer” includes mixtures of aptamers, reference to “a probe” includes mixtures of probes, and the like.

As used herein, the term “about” represents an insignificant modification or variation of the numerical value such that the basic function of the item to which the numerical value relates is unchanged.

As used herein, the terms “comprises,” “comprising,” “includes,” “including,” “contains,” “containing,” and any variations thereof, are intended to cover a non-exclusive inclusion, such that a process, method, product-by-process, or composition of matter that comprises, includes, or contains an element or list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, product-by-process, or composition of matter.

The present application includes biomarkers, methods, devices, reagents, systems, and kits for the detection and diagnosis of NSCLC and cancer more generally.

In one aspect, one or more biomarkers are provided for use either alone or in various combinations to diagnose NSCLC, permit the differential diagnosis of NSCLC from non-malignant conditions found in individuals with indeterminate pulmonary nodules identified with a CT scan or other imaging method, screening of high risk smokers for NSCLC, and diagnosing an individual with NSCLC, monitor NSCLC recurrence, or address other clinical indications. As described in detail below, exemplary embodiments include the biomarkers provided in Table 1, which were identified using a multiplex aptamer-based assay that is described generally in Example 1 and more specifically in Example 2.

Table 1 sets forth the findings obtained from analyzing hundreds of individual blood samples from NSCLC cases, and hundreds of equivalent individual control blood samples from high risk smokers and benign pulmonary nodules. The smokers and benign pulmonary nodules control group was designed to match the populations with which a NSCLC diagnostic test can have the most benefit, including asymptomatic individuals and symptomatic individuals. These cases and controls were obtained from multiple clinical sites to mimic the range of real world conditions under which such a test can be applied. The potential biomarkers were measured in individual samples rather than pooling the disease and control blood; this allowed a better understanding of the individual and group variations in the phenotypes associated with the presence and absence of disease (in this case NSCLC). Since over 1000 protein measurements were made on each sample, and several hundred samples from each of the disease and the control populations were individually measured, Table 1, resulted from an analysis of an uncommonly large set of data. The measurements were analyzed using the methods described in the section, “Classification of Biomarkers and Calculation of Disease Scores” herein. Table 1 lists the 59 biomarkers found to be useful in distinguishing samples obtained from individuals with NSCLC from “control” samples obtained from smokers and benign pulmonary nodules.

While certain of the described NSCLC biomarkers are useful alone for detecting and diagnosing NSCLC, methods are also described herein for the grouping of multiple subsets of the NSCLC biomarkers, where each grouping or subset selection is useful as a panel of three or more biomarkers, interchangeably referred to herein as a “biomarker panel” and a panel. Thus, various embodiments of the instant application provide combinations comprising N biomarkers, wherein N is at least two biomarkers. In other embodiments, N is selected from 2-59 biomarkers.

In yet other embodiments, N is selected to be any number from 2-5, 2-10, 2-15, 2-20, 2-25, 2-30, 2-35, 2-40, 2-45, 2-50, 2-55, or 2-59. In other embodiments, N is selected to be any number from 3-5, 3-10, 3-15, 3-20, 3-25, 3-30, 3-35, 3-40, 3-45, 3-50, 3-55, or 3-59. In other embodiments, N is selected to be any number from 4-5, 4-10, 4-15, 4-20, 4-25, 4-30, 4-35, 4-40, 4-45, 4-50, 4-55, or 4-59. In other embodiments, N is selected to be any number from 5-10, 5-15, 5-20, 5-25, 5-30, 5-35, 5-40, 5-45, 5-50, 5-55, or 5-59. In other embodiments, N is selected to be any number from 6-10, 6-15, 6-20, 6-25, 6-30, 6-35, 6-40, 6-45, 6-50, 6-55, or 6-59. In other embodiments, N is selected to be any number from 7-10, 7-15, 7-20, 7-25, 7-30, 7-35, 7-40, 7-45, 7-50, 7-55, or 7-59. In other embodiments, N is selected to be any number from 8-10, 8-15, 8-20, 8-25, 8-30, 8-35, 8-40, 8-45, 8-50, 8-55, or 8-59. In other embodiments, N is selected to be any number from 9-10, 9-15, 9-20, 9-25, 9-30, 9-35, 9-40, 9-45, 9-50, 9-55, or 9-59. In other embodiments, N is selected to be any number from 10-15, 10-20, 10-25, 10-30, 10-35, 10-40, 10-45, 10-50, 10-55, or 10-59. It will be appreciated that N can be selected to encompass similar, but higher order, ranges.

In one embodiment, the number of biomarkers useful for a biomarker subset or panel is based on the sensitivity and specificity value for the particular combination of biomarker values. The terms “sensitivity” and “specificity” are used herein with respect to the ability to correctly classify an individual, based on one or more biomarker values detected in their biological sample, as having NSCLC or not having NSCLC. “Sensitivity” indicates the performance of the biomarker(s) with respect to correctly classifying individuals that have NSCLC. “Specificity” indicates the performance of the biomarker(s) with respect to correctly classifying individuals who do not have NSCLC. For example, 85% specificity and 90% sensitivity for a panel of markers used to test a set of control samples and NSCLC samples indicates that 85% of the control samples were correctly classified as control samples by the panel, and 90% of the NSCLC samples were correctly classified as NSCLC samples by the panel. The desired or preferred minimum value can be determined as described in Example 3. Representative panels are set forth in Tables 4-11, which set forth a series of 100 different panels of 3-10 biomarkers, which have the indicated levels of specificity and sensitivity for each panel. The total number of occurrences of each marker in each of these panels is indicated in Table 12.

In one aspect, NSCLC is detected or diagnosed in an individual by conducting an assay on a biological sample from the individual and detecting biomarker values that each correspond to at least one of the biomarkers MMP7, CLIC1 or STX1A and at least N additional biomarkers selected from the list of biomarkers in Table 1, wherein N equals 2, 3, 4, 5, 6, 7, 8, or 9. In a further aspect, NSCLC is detected or diagnosed in an individual by conducting an assay on a biological sample from the individual and detecting biomarker values that each correspond to the biomarkers MMP7, CLIC1 or STX1A and one of at least N additional biomarkers selected from the list of biomarkers in Table 1, wherein N equals 1, 2, 3, 4, 5, 6, or 7. In a further aspect, NSCLC is detected or diagnosed in an individual by conducting an assay on a biological sample from the individual and detecting biomarker values that each correspond to the biomarker MMP7 and one of at least N additional biomarkers selected from the list of biomarkers in Table 1, wherein N equals 2, 3, 4, 5, 6, 7, 8, or 9. In a further aspect, NSCLC is detected or diagnosed in an individual by conducting an assay on a biological sample from the individual and detecting biomarker values that each correspond to the biomarker CLIC1 and one of at least N additional biomarkers selected from the list of biomarkers in Table 1, wherein N equals 2, 3, 4, 5, 6, 7, 8, or 9. In a further aspect, NSCLC is detected or diagnosed in an individual by conducting an assay on a biological sample from the individual and detecting biomarker values that each correspond to the biomarker STX1A and one of at least N additional biomarkers selected from the list of biomarkers in Table 1, wherein N equals 2, 3, 4, 5, 6, 7, 8, or 9.

The NSCLC biomarkers identified herein represent a relatively large number of choices for subsets or panels of biomarkers that can be used to effectively detect or diagnose NSCLC. Selection of the desired number of such biomarkers depends on the specific combination of biomarkers chosen. It is important to remember that panels of biomarkers for detecting or diagnosing NSCLC may also include biomarkers not found in Table 1, and that the inclusion of additional biomarkers not found in Table 1 may reduce the number of biomarkers in the particular subset or panel that is selected from Table 1. The number of biomarkers from Table 1 used in a subset or panel may also be reduced if additional biomedical information is used in conjunction with the biomarker values to establish acceptable sensitivity and specificity values for a given assay.

Another factor that can affect the number of biomarkers to be used in a subset or panel of biomarkers is the procedures used to obtain biological samples from individuals who are being diagnosed for NSCLC. In a carefully controlled sample procurement environment, the number of biomarkers necessary to meet desired sensitivity and specificity values will be lower than in a situation where there can be more variation in sample collection, handling and storage. In developing the list of biomarkers set forth in Table 1, multiple sample collection sites were utilized to collect data for classifier training. This provides for more robust biomarkers that are less sensitive to variations in sample collection, handling and storage, but can also require that the number of biomarkers in a subset or panel be larger than if the training data were all obtained under very similar conditions.

One aspect of the instant application can be described generally with reference to FIGS. 1A and 1B. A biological sample is obtained from an individual or individuals of interest. The biological sample is then assayed to detect the presence of one or more (N) biomarkers of interest and to determine a biomarker value for each of said N biomarkers (referred to in FIG. 1B as marker RFU). Once a biomarker has been detected and a biomarker value assigned each marker is scored or classified as described in detail herein. The marker scores are then combined to provide a total diagnostic score, which indicates the likelihood that the individual from whom the sample was obtained has NSCLC.

As used herein, “lung” may be interchangeably referred to as “pulmonary”.

As used herein, “smoker” refers to an individual who has a history of tobacco smoke inhalation.

“Biological sample”, “sample”, and “test sample” are used interchangeably herein to refer to any material, biological fluid, tissue, or cell obtained or otherwise derived from an individual. This includes blood (including whole blood, leukocytes, peripheral blood mononuclear cells, buffy coat, plasma, and serum), sputum, tears, mucus, nasal washes, nasal aspirate, breath, urine, semen, saliva, peritoneal washings, cystic fluid, meningeal fluid, amniotic fluid, glandular fluid, lymph fluid, cytologic fluid, ascites, pleural fluid, nipple aspirate, bronchial aspirate, bronchial brushing, synovial fluid, joint aspirate, organ secretions, cells, a cellular extract, and cerebrospinal fluid. This also includes experimentally separated fractions of all of the preceding. For example, a blood sample can be fractionated into serum, plasma or into fractions containing particular types of blood cells, such as red blood cells or white blood cells (leukocytes). If desired, a sample can be a combination of samples from an individual, such as a combination of a tissue and fluid sample. The term “biological sample” also includes materials containing homogenized solid material, such as from a stool sample, a tissue sample, or a tissue biopsy, for example. The term “biological sample” also includes materials derived from a tissue culture or a cell culture. Any suitable methods for obtaining a biological sample can be employed; exemplary methods include, e.g., phlebotomy, swab (e.g., buccal swab), and a fine needle aspirate biopsy procedure. Exemplary tissues susceptible to fine needle aspiration include lymph node, lung, lung washes, BAL (bronchoalveolar lavage),pleura, thyroid, breast, pancreas and liver. Samples can also be collected, e.g., by micro dissection (e.g., laser capture micro dissection (LCM) or laser micro dissection (LMD)), bladder wash, smear (e.g., a PAP smear), or ductal lavage. A “biological sample” obtained or derived from an individual includes any such sample that has been processed in any suitable manner after being obtained from the individual.

Further, it should be realized that a biological sample can be derived by taking biological samples from a number of individuals and pooling them or pooling an aliquot of each individual's biological sample. The pooled sample can be treated as a sample from a single individual and if the presence of cancer is established in the pooled sample, then each individual biological sample can be re-tested to determine which individual(s) have NSCLC.

For purposes of this specification, the phrase “data attributed to a biological sample from an individual” is intended to mean that the data in some form derived from, or were generated using, the biological sample of the individual. The data may have been reformatted, revised, or mathematically altered to some degree after having been generated, such as by conversion from units in one measurement system to units in another measurement system; but, the data are understood to have been derived from, or were generated using, the biological sample.

“Target”, “target molecule”, and “analyte” are used interchangeably herein to refer to any molecule of interest that may be present in a biological sample. A “molecule of interest” includes any minor variation of a particular molecule, such as, in the case of a protein, for example, minor variations in amino acid sequence, disulfide bond formation, glycosylation, lipidation, acetylation, phosphorylation, or any other manipulation or modification, such as conjugation with a labeling component, which does not substantially alter the identity of the molecule. A “target molecule”, “target”, or “analyte” is a set of copies of one type or species of molecule or multi-molecular structure. “Target molecules”, “targets”, and “analytes” refer to more than one such set of molecules. Exemplary target molecules include proteins, polypeptides, nucleic acids, carbohydrates, lipids, polysaccharides, glycoproteins, hormones, receptors, antigens, antibodies, affybodies, autoantibodies, antibody mimics, viruses, pathogens, toxic substances, substrates, metabolites, transition state analogs, cofactors, inhibitors, drugs, dyes, nutrients, growth factors, cells, tissues, and any fragment or portion of any of the foregoing.

As used herein, “polypeptide,” “peptide,” and “protein” are used interchangeably herein to refer to polymers of amino acids of any length. The polymer may be linear or branched, it may comprise modified amino acids, and it may be interrupted by non-amino acids. The terms also encompass an amino acid polymer that has been modified naturally or by intervention; for example, disulfide bond formation, glycosylation, lipidation, acetylation, phosphorylation, or any other manipulation or modification, such as conjugation with a labeling component. Also included within the definition are, for example, polypeptides containing one or more analogs of an amino acid (including, for example, unnatural amino acids, etc.), as well as other modifications known in the art. Polypeptides can be single chains or associated chains. Also included within the definition are preproteins and intact mature proteins; peptides or polypeptides derived from a mature protein; fragments of a protein; splice variants; recombinant forms of a protein; protein variants with amino acid modifications, deletions, or substitutions; digests; and post-translational modifications, such as glycosylation, acetylation, phosphorylation, and the like.

As used herein, “marker” and “biomarker” are used interchangeably to refer to a target molecule that indicates or is a sign of a normal or abnormal process in an individual or of a disease or other condition in an individual. More specifically, a “marker” or “biomarker” is an anatomic, physiologic, biochemical, or molecular parameter associated with the presence of a specific physiological state or process, whether normal or abnormal, and, if abnormal, whether chronic or acute. Biomarkers are detectable and measurable by a variety of methods including laboratory assays and medical imaging. When a biomarker is a protein, it is also possible to use the expression of the corresponding gene as a surrogate measure of the amount or presence or absence of the corresponding protein biomarker in a biological sample or methylation state of the gene encoding the biomarker or proteins that control expression of the biomarker.

As used herein, “biomarker value”, “value”, “biomarker level”, and “level” are used interchangeably to refer to a measurement that is made using any analytical method for detecting the biomarker in a biological sample and that indicates the presence, absence, absolute amount or concentration, relative amount or concentration, titer, a level, an expression level, a ratio of measured levels, or the like, of, for, or corresponding to the biomarker in the biological sample. The exact nature of the “value” or “level” depends on the specific design and components of the particular analytical method employed to detect the biomarker.

When a biomarker indicates or is a sign of an abnormal process or a disease or other condition in an individual, that biomarker is generally described as being either overexpressed or under-expressed as compared to an expression level or value of the biomarker that indicates or is a sign of a normal process or an absence of a disease or other condition in an individual. “Up-regulation”, “up-regulated”, “over-expression”, “over-expressed”, and any variations thereof are used interchangeably to refer to a value or level of a biomarker in a biological sample that is greater than a value or level (or range of values or levels) of the biomarker that is typically detected in similar biological samples from healthy or normal individuals. The terms may also refer to a value or level of a biomarker in a biological sample that is greater than a value or level (or range of values or levels) of the biomarker that may be detected at a different stage of a particular disease.

“Down-regulation”, “down-regulated”, “under-expression”, “under-expressed”, and any variations thereof are used interchangeably to refer to a value or level of a biomarker in a biological sample that is less than a value or level (or range of values or levels) of the biomarker that is typically detected in similar biological samples from healthy or normal individuals. The terms may also refer to a value or level of a biomarker in a biological sample that is less than a value or level (or range of values or levels) of the biomarker that may be detected at a different stage of a particular disease.

Further, a biomarker that is either over-expressed or under-expressed can also be referred to as being “differentially expressed” or as having a “differential level” or “differential value” as compared to a “normal” expression level or value of the biomarker that indicates or is a sign of a normal process or an absence of a disease or other condition in an individual. Thus, “differential expression” of a biomarker can also be referred to as a variation from a “normal” expression level of the biomarker.

The term “differential gene expression” and “differential expression” are used interchangeably to refer to a gene (or its corresponding protein expression product) whose expression is activated to a higher or lower level in a subject suffering from a specific disease, relative to its expression in a normal or control subject. The terms also include genes (or the corresponding protein expression products) whose expression is activated to a higher or lower level at different stages of the same disease. It is also understood that a differentially expressed gene may be either activated or inhibited at the nucleic acid level or protein level, or may be subject to alternative splicing to result in a different polypeptide product. Such differences may be evidenced by a variety of changes including mRNA levels, surface expression, secretion or other partitioning of a polypeptide. Differential gene expression may include a comparison of expression between two or more genes or their gene products; or a comparison of the ratios of the expression between two or more genes or their gene products; or even a comparison of two differently processed products of the same gene, which differ between normal subjects and subjects suffering from a disease; or between various stages of the same disease. Differential expression includes both quantitative, as well as qualitative, differences in the temporal or cellular expression pattern in a gene or its expression products among, for example, normal and diseased cells, or among cells which have undergone different disease events or disease stages.

As used herein, “individual” refers to a test subject or patient. The individual can be a mammal or a non-mammal. In various embodiments, the individual is a mammal. A mammalian individual can be a human or non-human. In various embodiments, the individual is a human. A healthy or normal individual is an individual in which the disease or condition of interest (including, for example, lung diseases, lung-associated diseases, or other lung conditions) is not detectable by conventional diagnostic methods.

“Diagnose”, “diagnosing”, “diagnosis”, and variations thereof refer to the detection, determination, or recognition of a health status or condition of an individual on the basis of one or more signs, symptoms, data, or other information pertaining to that individual. The health status of an individual can be diagnosed as healthy/normal (i.e., a diagnosis of the absence of a disease or condition) or diagnosed as ill/abnormal (i.e., a diagnosis of the presence, or an assessment of the characteristics, of a disease or condition). The terms “diagnose”, “diagnosing”, “diagnosis”, etc., encompass, with respect to a particular disease or condition, the initial detection of the disease; the characterization or classification of the disease; the detection of the progression, remission, or recurrence of the disease; and the detection of disease response after the administration of a treatment or therapy to the individual. The diagnosis of NSCLC includes distinguishing individuals who have cancer from individuals who do not. It further includes distinguishing smokers and benign pulmonary nodules from NSCLC.

“Prognose”, “prognosing”, “prognosis”, and variations thereof refer to the prediction of a future course of a disease or condition in an individual who has the disease or condition (e.g., predicting patient survival), and such terms encompass the evaluation of disease response after the administration of a treatment or therapy to the individual.

“Evaluate”, “evaluating”, “evaluation”, and variations thereof encompass both “diagnose” and “prognose” and also encompass determinations or predictions about the future course of a disease or condition in an individual who does not have the disease as well as determinations or predictions regarding the likelihood that a disease or condition will recur in an individual who apparently has been cured of the disease. The term “evaluate” also encompasses assessing an individual's response to a therapy, such as, for example, predicting whether an individual is likely to respond favorably to a therapeutic agent or is unlikely to respond to a therapeutic agent (or will experience toxic or other undesirable side effects, for example), selecting a therapeutic agent for administration to an individual, or monitoring or determining an individual's response to a therapy that has been administered to the individual. Thus, “evaluating” NSCLC can include, for example, any of the following: prognosing the future course of NSCLC in an individual; predicting the recurrence of NSCLC in an individual who apparently has been cured of NSCLC; or determining or predicting an individual's response to a NSCLC treatment or selecting a NSCLC treatment to administer to an individual based upon a determination of the biomarker values derived from the individual's biological sample.

Any of the following examples may be referred to as either “diagnosing” or “evaluating” NSCLC: initially detecting the presence or absence of NSCLC; determining a specific stage, type or sub-type, or other classification or characteristic of NSCLC; determining whether a suspicious lung nodule or mass is benign or malignant NSCLC; or detecting/monitoring NSCLC progression (e.g., monitoring tumor growth or metastatic spread), remission, or recurrence.

As used herein, “additional biomedical information” refers to one or more evaluations of an individual, other than using any of the biomarkers described herein, that are associated with cancer risk or, more specifically, NSCLC risk. “Additional biomedical information” includes any of the following: physical descriptors of an individual, physical descriptors of a pulmonary nodule observed by CT imaging, the height and/or weight of an individual, the gender of an individual, the ethnicity of an individual, smoking history, occupational history, exposure to known carcinogens (e.g., exposure to any of asbestos, radon gas, chemicals, smoke from fires, and air pollution, which can include emissions from stationary or mobile sources such as industrial/factory or auto/marine/aircraft emissions), exposure to second-hand smoke, family history of NSCLC (or other cancer), the presence of pulmonary nodules, size of nodules, location of nodules, morphology of nodules (e.g., as observed through CT imaging, ground glass opacity (GGO), solid, non-solid), edge characteristics of the nodule (e.g., smooth, lobulated, sharp and smooth, spiculated, infiltrating), and the like. Smoking history is usually quantified in terms of “pack years”, which refers to the number of years a person has smoked multiplied by the average number of packs smoked per day. For example, a person who has smoked, on average, one pack of cigarettes per day for 35 years is referred to as having 35 pack years of smoking history. Additional biomedical information can be obtained from an individual using routine techniques known in the art, such as from the individual themselves by use of a routine patient questionnaire or health history questionnaire, etc., or from a medical practitioner, etc. Alternately, additional biomedical information can be obtained from routine imaging techniques, including CT imaging (e.g., low-dose CT imaging) and X-ray. Testing of biomarker levels in combination with an evaluation of any additional biomedical information may, for example, improve sensitivity, specificity, and/or AUC for detecting NSCLC (or other NSCLC-related uses) as compared to biomarker testing alone or evaluating any particular item of additional biomedical information alone (e.g., CT imaging alone).

The term “area under the curve” or “AUC” refers to the area under the curve of a receiver operating characteristic (ROC) curve, both of which are well known in the art. AUC measures are useful for comparing the accuracy of a classifier across the complete data range. Classifiers with a greater AUC have a greater capacity to classify unknowns correctly between two groups of interest (e.g., NSCLC samples and normal or control samples). ROC curves are useful for plotting the performance of a particular feature (e.g., any of the biomarkers described herein and/or any item of additional biomedical information) in distinguishing between two populations (e.g., cases having NSCLC and controls without NSCLC). Typically, the feature data across the entire population (e.g., the cases and controls) are sorted in ascending order based on the value of a single feature. Then, for each value for that feature, the true positive and false positive rates for the data are calculated. The true positive rate is determined by counting the number of cases above the value for that feature and then dividing by the total number of cases. The false positive rate is determined by counting the number of controls above the value for that feature and then dividing by the total number of controls. Although this definition refers to scenarios in which a feature is elevated in cases compared to controls, this definition also applies to scenarios in which a feature is lower in cases compared to the controls (in such a scenario, samples below the value for that feature would be counted). ROC curves can be generated for a single feature as well as for other single outputs, for example, a combination of two or more features can be mathematically combined (e.g., added, subtracted, multiplied, etc.) to provide a single sum value, and this single sum value can be plotted in a ROC curve. Additionally, any combination of multiple features, in which the combination derives a single output value, can be plotted in a ROC curve. These combinations of features may comprise a test. The ROC curve is the plot of the true positive rate (sensitivity) of a test against the false positive rate (1-specificity) of the test.

As used herein, “detecting” or “determining” with respect to a biomarker value includes the use of both the instrument required to observe and record a signal corresponding to a biomarker value and the material/s required to generate that signal. In various embodiments, the biomarker value is detected using any suitable method, including fluorescence, chemiluminescence, surface plasmon resonance, surface acoustic waves, mass spectrometry, infrared spectroscopy, Raman spectroscopy, atomic force microscopy, scanning tunneling microscopy, electrochemical detection methods, nuclear magnetic resonance, quantum dots, and the like.

“Solid support” refers herein to any substrate having a surface to which molecules may be attached, directly or indirectly, through either covalent or non-covalent bonds. A “solid support” can have a variety of physical formats, which can include, for example, a membrane; a chip (e.g., a protein chip); a slide (e.g., a glass slide or coverslip); a column; a hollow, solid, semi-solid, pore- or cavity-containing particle, such as, for example, a bead; a gel; a fiber, including a fiber optic material; a matrix; and a sample receptacle. Exemplary sample receptacles include sample wells, tubes, capillaries, vials, and any other vessel, groove or indentation capable of holding a sample. A sample receptacle can be contained on a multi-sample platform, such as a microtiter plate, slide, microfluidics device, and the like. A support can be composed of a natural or synthetic material, an organic or inorganic material. The composition of the solid support on which capture reagents are attached generally depends on the method of attachment (e.g., covalent attachment). Other exemplary receptacles include microdroplets and microfluidic controlled or bulk oil/aqueous emulsions within which assays and related manipulations can occur. Suitable solid supports include, for example, plastics, resins, polysaccharides, silica or silica-based materials, functionalized glass, modified silicon, carbon, metals, inorganic glasses, membranes, nylon, natural fibers (such as, for example, silk, wool and cotton), polymers, and the like. The material composing the solid support can include reactive groups such as, for example, carboxy, amino, or hydroxyl groups, which are used for attachment of the capture reagents. Polymeric solid supports can include, e.g., polystyrene, polyethylene glycol tetraphthalate, polyvinyl acetate, polyvinyl chloride, polyvinyl pyrrolidone, polyacrylonitrile, polymethyl methacrylate, polytetrafluoroethylene, butyl rubber, styrenebutadiene rubber, natural rubber, polyethylene, polypropylene, (poly)tetrafluoroethylene, (poly)vinylidenefluoride, polycarbonate, and polymethylpentene. Suitable solid support particles that can be used include, e.g., encoded particles, such as Luminex-type encoded particles, magnetic particles, and glass particles.

Exemplary Uses of Biomarkers

In various exemplary embodiments, methods are provided for diagnosing NSCLC in an individual by detecting one or more biomarker values corresponding to one or more biomarkers that are present in the circulation of an individual, such as in serum or plasma, by any number of analytical methods, including any of the analytical methods described herein. These biomarkers are, for example, differentially expressed in individuals with NSCLC as compared to individuals without NSCLC. Detection of the differential expression of a biomarker in an individual can be used, for example, to permit the early diagnosis of NSCLC, to distinguish between a benign and malignant pulmonary nodule (such as, for example, a nodule observed on a computed tomography (CT) scan), to monitor NSCLC recurrence, or for other clinical indications.

Any of the biomarkers described herein may be used in a variety of clinical indications for NSCLC, including any of the following: detection of NSCLC (such as in a high-risk individual or population); characterizing NSCLC (e.g., determining NSCLC type, sub-type, or stage), such as by distinguishing between non-small cell lung cancer (NSCLC) and small cell lung cancer (SCLC) and/or between adenocarcinoma and squamous cell carcinoma (or otherwise facilitating histopathology); determining whether a lung nodule is a benign nodule or a malignant lung tumor; determining NSCLC prognosis; monitoring NSCLC progression or remission; monitoring for NSCLC recurrence; monitoring metastasis; treatment selection; monitoring response to a therapeutic agent or other treatment; stratification of individuals for computed tomography (CT) screening (e.g., identifying those individuals at greater risk of NSCLC and thereby most likely to benefit from spiral-CT screening, thus increasing the positive predictive value of CT); combining biomarker testing with additional biomedical information, such as smoking history, etc., or with nodule size, morphology, etc. (such as to provide an assay with increased diagnostic performance compared to CT testing or biomarker testing alone); facilitating the diagnosis of a pulmonary nodule as malignant or benign; facilitating clinical decision making once a pulmonary nodule is observed on CT (e.g., ordering repeat CT scans if the nodule is deemed to be low risk, such as if a biomarker-based test is negative, with or without categorization of nodule size, or considering biopsy if the nodule is deemed medium to high risk, such as if a biomarker-based test is positive, with or without categorization of nodule size); and facilitating decisions regarding clinical follow-up (e.g., whether to implement repeat CT scans, fine needle biopsy, nodule resection or thoracotomy after observing a non-calcified nodule on CT). Biomarker testing may improve positive predictive value (PPV) over CT or chest X-ray screening of high risk individuals alone. In addition to their utilities in conjunction with CT screening, the biomarkers described herein can also be used in conjunction with any other imaging modalities used for NSCLC, such as chest X-ray, bronchoscopy or fluorescent bronchoscopy, MRI or PET scan. Furthermore, the described biomarkers may also be useful in permitting certain of these uses before indications of NSCLC are detected by imaging modalities or other clinical correlates, or before symptoms appear. It further includes distinguishing individuals with indeterminate pulmonary nodules identified with a CT scan or other imaging method, screening of high risk smokers for NSCLC, and diagnosing an individual with NSCLC.

As an example of the manner in which any of the biomarkers described herein can be used to diagnose NSCLC, differential expression of one or more of the described biomarkers in an individual who is not known to have NSCLC may indicate that the individual has NSCLC, thereby enabling detection of NSCLC at an early stage of the disease when treatment is most effective, perhaps before the NSCLC is detected by other means or before symptoms appear. Over-expression of one or more of the biomarkers during the course of NSCLC may be indicative of NSCLC progression, e.g., a NSCLC tumor is growing and/or metastasizing (and thus indicate a poor prognosis), whereas a decrease in the degree to which one or more of the biomarkers is differentially expressed (i.e., in subsequent biomarker tests, the expression level in the individual is moving toward or approaching a “normal” expression level) may be indicative of NSCLC remission, e.g., a NSCLC tumor is shrinking (and thus indicate a good or better prognosis). Similarly, an increase in the degree to which one or more of the biomarkers is differentially expressed (i.e., in subsequent biomarker tests, the expression level in the individual is moving further away from a “normal” expression level) during the course of NSCLC treatment may indicate that the NSCLC is progressing and therefore indicate that the treatment is ineffective, whereas a decrease in differential expression of one or more of the biomarkers during the course of NSCLC treatment may be indicative of NSCLC remission and therefore indicate that the treatment is working successfully. Additionally, an increase or decrease in the differential expression of one or more of the biomarkers after an individual has apparently been cured of NSCLC may be indicative of NSCLC recurrence. In a situation such as this, for example, the individual can be re-started on therapy (or the therapeutic regimen modified such as to increase dosage amount and/or frequency, if the individual has maintained therapy) at an earlier stage than if the recurrence of NSCLC was not detected until later. Furthermore, a differential expression level of one or more of the biomarkers in an individual may be predictive of the individual's response to a particular therapeutic agent. In monitoring for NSCLC recurrence or progression, changes in the biomarker expression levels may indicate the need for repeat imaging (e.g., repeat CT scanning), such as to determine NSCLC activity or to determine the need for changes in treatment.

Detection of any of the biomarkers described herein may be particularly useful following, or in conjunction with, NSCLC treatment, such as to evaluate the success of the treatment or to monitor NSCLC remission, recurrence, and/or progression (including metastasis) following treatment. NSCLC treatment may include, for example, administration of a therapeutic agent to the individual, performance of surgery (e.g., surgical resection of at least a portion of a NSCLC tumor or removal of NSCLC and surrounding tissue), administration of radiation therapy, or any other type of NSCLC treatment used in the art, and any combination of these treatments. Lung cancer treatment may include, for example, administration of a therapeutic agent to the individual, performance of surgery (e.g., surgical resection of at least a portion of a lung tumor), administration of radiation therapy, or any other type of NSCLC treatment used in the art, and any combination of these treatments. For example, siRNA molecules are synthetic double stranded RNA molecules that inhibit gene expression and may serve as targeted lung cancer therapeutics. For example, any of the biomarkers may be detected at least once after treatment or may be detected multiple times after treatment (such as at periodic intervals), or may be detected both before and after treatment. Differential expression levels of any of the biomarkers in an individual over time may be indicative of NSCLC progression, remission, or recurrence, examples of which include any of the following: an increase or decrease in the expression level of the biomarkers after treatment compared with the expression level of the biomarker before treatment; an increase or decrease in the expression level of the biomarker at a later time point after treatment compared with the expression level of the biomarker at an earlier time point after treatment; and a differential expression level of the biomarker at a single time point after treatment compared with normal levels of the biomarker.

As a specific example, the biomarker levels for any of the biomarkers described herein can be determined in pre-surgery and post-surgery (e.g., 2-16 weeks after surgery) serum or plasma samples. An increase in the biomarker expression level(s) in the post-surgery sample compared with the pre-surgery sample can indicate progression of NSCLC (e.g., unsuccessful surgery), whereas a decrease in the biomarker expression level(s) in the post-surgery sample compared with the pre-surgery sample can indicate regression of NSCLC (e.g., the surgery successfully removed the lung tumor). Similar analyses of the biomarker levels can be carried out before and after other forms of treatment, such as before and after radiation therapy or administration of a therapeutic agent or cancer vaccine.

In addition to testing biomarker levels as a stand-alone diagnostic test, biomarker levels can also be done in conjunction with determination of SNPs or other genetic lesions or variability that are indicative of increased risk of susceptibility of disease. (See, e.g., Amos et al., Nature Genetics 40, 616-622 (2009)).

In addition to testing biomarker levels as a stand-alone diagnostic test, biomarker levels can also be done in conjunction with radiologic screening, such as CT screening. For example, the biomarkers may facilitate the medical and economic justification for implementing CT screening, such as for screening large asymptomatic populations at risk for NSCLC (e.g., smokers). For example, a “pre-CT” test of biomarker levels could be used to stratify high-risk individuals for CT screening, such as for identifying those who are at highest risk for NSCLC based on their biomarker levels and who should be prioritized for CT screening. If a CT test is implemented, biomarker levels (e.g., as determined by an aptamer assay of serum or plasma samples) of one or more biomarkers can be measured and the diagnostic score could be evaluated in conjunction with additional biomedical information (e.g., tumor parameters determined by CT testing) to enhance positive predictive value (PPV) over CT or biomarker testing alone. A “post-CT” aptamer panel for determining biomarker levels can be used to determine the likelihood that a pulmonary nodule observed by CT (or other imaging modality) is malignant or benign.

Detection of any of the biomarkers described herein may be useful for post-CT testing. For example, biomarker testing may eliminate or reduce a significant number of false positive tests over CT alone. Further, biomarker testing may facilitate treatment of patients. By way of example, if a lung nodule is less than 5 mm in size, results of biomarker testing may advance patients from “watch and wait” to biopsy at an earlier time; if a lung nodule is 5-9 mm, biomarker testing may eliminate the use of a biopsy or thoracotomy on false positive scans; and if a lung nodule is larger than 10 mm, biomarker testing may eliminate surgery for a sub-population of these patients with benign nodules. Eliminating the need for biopsy in some patients based on biomarker testing would be beneficial because there is significant morbidity associated with nodule biopsy and difficulty in obtaining nodule tissue depending on the location of nodule. Similarly, eliminating the need for surgery in some patients, such as those whose nodules are actually benign, would avoid unnecessary risks and costs associated with surgery.

In addition to testing biomarker levels in conjunction with radiologic screening in high risk individuals (e.g., assessing biomarker levels in conjunction with size or other characteristics of a lung nodule or mass observed on an imaging scan), information regarding the biomarkers can also be evaluated in conjunction with other types of data, particularly data that indicates an individual's risk for NSCLC (e.g., patient clinical history, occupational exposure history, symptoms, family history of cancer, risk factors such as whether or not the individual was a smoker, and/or status of other biomarkers, etc.). These various data can be assessed by automated methods, such as a computer program/software, which can be embodied in a computer or other apparatus/device.

Any of the described biomarkers may also be used in imaging tests. For example, an imaging agent can be coupled to any of the described biomarkers, which can be used to aid in NSCLC diagnosis, to monitor disease progression/remission or metastasis, to monitor for disease recurrence, or to monitor response to therapy, among other uses.

Detection and Determination of Biomarkers and Biomarker Values

A biomarker value for the biomarkers described herein can be detected using any of a variety of known analytical methods. In one embodiment, a biomarker value is detected using a capture reagent. As used herein, a “capture agent” or “capture reagent” refers to a molecule that is capable of binding specifically to a biomarker. In various embodiments, the capture reagent can be exposed to the biomarker in solution or can be exposed to the biomarker while the capture reagent is immobilized on a solid support. In other embodiments, the capture reagent contains a feature that is reactive with a secondary feature on a solid support. In these embodiments, the capture reagent can be exposed to the biomarker in solution, and then the feature on the capture reagent can be used in conjunction with the secondary feature on the solid support to immobilize the biomarker on the solid support. The capture reagent is selected based on the type of analysis to be conducted. Capture reagents include but are not limited to aptamers, antibodies, antigens, adnectins, ankyrins, other antibody mimetics and other protein scaffolds, autoantibodies, chimeras, small molecules, an F(ab′)₂ fragment, a single chain antibody fragment, an Fv fragment, a single chain Fv fragment, a nucleic acid, a lectin, a ligand-binding receptor, affybodies, nanobodies, imprinted polymers, avimers, peptidomimetics, a hormone receptor, a cytokine receptor, and synthetic receptors, and modifications and fragments of these.

In some embodiments, a biomarker value is detected using a biomarker/capture reagent complex.

In other embodiments, the biomarker value is derived from the biomarker/capture reagent complex and is detected indirectly, such as, for example, as a result of a reaction that is subsequent to the biomarker/capture reagent interaction, but is dependent on the formation of the biomarker/capture reagent complex.

In some embodiments, the biomarker value is detected directly from the biomarker in a biological sample.

In one embodiment, the biomarkers are detected using a multiplexed format that allows for the simultaneous detection of two or more biomarkers in a biological sample. In one embodiment of the multiplexed format, capture reagents are immobilized, directly or indirectly, covalently or non-covalently, in discrete locations on a solid support. In another embodiment, a multiplexed format uses discrete solid supports where each solid support has a unique capture reagent associated with that solid support, such as, for example quantum dots. In another embodiment, an individual device is used for the detection of each one of multiple biomarkers to be detected in a biological sample. Individual devices can be configured to permit each biomarker in the biological sample to be processed simultaneously. For example, a microtiter plate can be used such that each well in the plate is used to uniquely analyze one of multiple biomarkers to be detected in a biological sample.

In one or more of the foregoing embodiments, a fluorescent tag can be used to label a component of the biomarker/capture complex to enable the detection of the biomarker value. In various embodiments, the fluorescent label can be conjugated to a capture reagent specific to any of the biomarkers described herein using known techniques, and the fluorescent label can then be used to detect the corresponding biomarker value. Suitable fluorescent labels include rare earth chelates, fluorescein and its derivatives, rhodamine and its derivatives, dansyl, allophycocyanin, PBXL-3, Qdot 605, Lissamine, phycoerythrin, Texas Red, and other such compounds.

In one embodiment, the fluorescent label is a fluorescent dye molecule. In some embodiments, the fluorescent dye molecule includes at least one substituted indolium ring system in which the substituent on the 3-carbon of the indolium ring contains a chemically reactive group or a conjugated substance. In some embodiments, the dye molecule includes an AlexaFluor molecule, such as, for example, AlexaFluor 488, AlexaFluor 532, AlexaFluor 647, AlexaFluor 680, or AlexaFluor 700. In other embodiments, the dye molecule includes a first type and a second type of dye molecule, such as, e.g., two different AlexaFluor molecules. In other embodiments, the dye molecule includes a first type and a second type of dye molecule, and the two dye molecules have different emission spectra.

Fluorescence can be measured with a variety of instrumentation compatible with a wide range of assay formats. For example, spectrofluorimeters have been designed to analyze microtiter plates, microscope slides, printed arrays, cuvettes, etc. See Principles of Fluorescence Spectroscopy, by J. R. Lakowicz, Springer Science+Business Media, Inc., 2004. See Bioluminescence & Chemiluminescence: Progress & Current Applications; Philip E. Stanley and Larry J. Kricka editors, World Scientific Publishing Company, January 2002.

In one or more of the foregoing embodiments, a chemiluminescence tag can optionally be used to label a component of the biomarker/capture complex to enable the detection of a biomarker value. Suitable chemiluminescent materials include any of oxalyl chloride, Rodamin 6G, Ru(bipy)₃ ²⁺, TMAE (tetrakis(dimethylamino)ethylene), Pyrogallol (1,2,3-trihydroxibenzene), Lucigenin, peroxyoxalates, Aryl oxalates, Acridinium esters, dioxetanes, and others.

In yet other embodiments, the detection method includes an enzyme/substrate combination that generates a detectable signal that corresponds to the biomarker value. Generally, the enzyme catalyzes a chemical alteration of the chromogenic substrate which can be measured using various techniques, including spectrophotometry, fluorescence, and chemiluminescence. Suitable enzymes include, for example, luciferases, luciferin, malate dehydrogenase, urease, horseradish peroxidase (HRPO), alkaline phosphatase, beta-galactosidase, glucoamylase, lysozyme, glucose oxidase, galactose oxidase, and glucose-6-phosphate dehydrogenase, uricase, xanthine oxidase, lactoperoxidase, microperoxidase, and the like.

In yet other embodiments, the detection method can be a combination of fluorescence, chemiluminescence, radionuclide or enzyme/substrate combinations that generate a measurable signal. Multimodal signaling could have unique and advantageous characteristics in biomarker assay formats.

More specifically, the biomarker values for the biomarkers described herein can be detected using known analytical methods including, singleplex aptamer assays, multiplexed aptamer assays, singleplex or multiplexed immunoassays, mRNA expression profiling, miRNA expression profiling, mass spectrometric analysis, histological/cytological methods, etc. as detailed below.

Determination of Biomarker Values Using Aptamer-Based Assays

Assays directed to the detection and quantification of physiologically significant molecules in biological samples and other samples are important tools in scientific research and in the health care field. One class of such assays involves the use of a microarray that includes one or more aptamers immobilized on a solid support. The aptamers are each capable of binding to a target molecule in a highly specific manner and with very high affinity. See, e.g., U.S. Pat. No. 5,475,096 entitled “Nucleic Acid Ligands”; see also, e.g., U.S. Pat. No. 6,242,246, U.S. Pat. No. 6,458,543, and U.S. Pat. No. 6,503,715, each of which is entitled “Nucleic Acid Ligand Diagnostic Biochip”. Once the microarray is contacted with a sample, the aptamers bind to their respective target molecules present in the sample and thereby enable a determination of a biomarker value corresponding to a biomarker.

As used herein, an “aptamer” refers to a nucleic acid that has a specific binding affinity for a target molecule. It is recognized that affinity interactions are a matter of degree; however, in this context, the “specific binding affinity” of an aptamer for its target means that the aptamer binds to its target generally with a much higher degree of affinity than it binds to other components in a test sample. An “aptamer” is a set of copies of one type or species of nucleic acid molecule that has a particular nucleotide sequence. An aptamer can include any suitable number of nucleotides, including any number of chemically modified nucleotides. “Aptamers” refers to more than one such set of molecules. Different aptamers can have either the same or different numbers of nucleotides. Aptamers can be DNA or RNA or chemically modified nucleic acids and can be single stranded, double stranded, or contain double stranded regions, and can include higher ordered structures. An aptamer can also be a photoaptamer, where a photoreactive or chemically reactive functional group is included in the aptamer to allow it to be covalently linked to its corresponding target. Any of the aptamer methods disclosed herein can include the use of two or more aptamers that specifically bind the same target molecule. As further described below, an aptamer may include a tag. If an aptamer includes a tag, all copies of the aptamer need not have the same tag. Moreover, if different aptamers each include a tag, these different aptamers can have either the same tag or a different tag.

An aptamer can be identified using any known method, including the SELEX process. Once identified, an aptamer can be prepared or synthesized in accordance with any known method, including chemical synthetic methods and enzymatic synthetic methods.

As used herein, a “SOMAmer” or Slow Off-Rate Modified Aptamer refers to an aptamer having improved off-rate characteristics. SOMAmers can be generated using the improved SELEX methods described in U.S. Publication No. 2009/0004667, entitled “Method for Generating Aptamers with Improved Off-Rates.”

The terms “SELEX” and “SELEX process” are used interchangeably herein to refer generally to a combination of (1) the selection of aptamers that interact with a target molecule in a desirable manner, for example binding with high affinity to a protein, with (2) the amplification of those selected nucleic acids. The SELEX process can be used to identify aptamers with high affinity to a specific target or biomarker.

SELEX generally includes preparing a candidate mixture of nucleic acids, binding of the candidate mixture to the desired target molecule to form an affinity complex, separating the affinity complexes from the unbound candidate nucleic acids, separating and isolating the nucleic acid from the affinity complex, purifying the nucleic acid, and identifying a specific aptamer sequence. The process may include multiple rounds to further refine the affinity of the selected aptamer. The process can include amplification steps at one or more points in the process. See, e.g., U.S. Pat. No. 5,475,096, entitled “Nucleic Acid Ligands”. The SELEX process can be used to generate an aptamer that covalently binds its target as well as an aptamer that non-covalently binds its target. See, e.g., U.S. Pat. No. 5,705,337 entitled “Systematic Evolution of Nucleic Acid Ligands by Exponential Enrichment: ChemiSELEX.”

The SELEX process can be used to identify high-affinity aptamers containing modified nucleotides that confer improved characteristics on the aptamer, such as, for example, improved in vivo stability or improved delivery characteristics. Examples of such modifications include chemical substitutions at the ribose and/or phosphate and/or base positions. SELEX process-identified aptamers containing modified nucleotides are described in U.S. Pat. No. 5,660,985, entitled “High Affinity Nucleic Acid Ligands Containing Modified Nucleotides”, which describes oligonucleotides containing nucleotide derivatives chemically modified at the 5′- and 2′-positions of pyrimidines. U.S. Pat. No. 5,580,737, see supra, describes highly specific aptamers containing one or more nucleotides modified with 2′-amino (2′-NH₂), 2′-fluoro (2′-F), and/or 2′-O-methyl (2′-OMe). See also, U.S. Patent Application Publication 2009/0098549, entitled “SELEX and PHOTOSELEX”, which describes nucleic acid libraries having expanded physical and chemical properties and their use in SELEX and photoSELEX.

SELEX can also be used to identify aptamers that have desirable off-rate characteristics. See U.S. Patent Application Publication 2009/0004667, entitled “Method for Generating Aptamers with Improved Off-Rates”, which describes improved SELEX methods for generating aptamers that can bind to target molecules. Methods for producing aptamers and photoaptamers having slower rates of dissociation from their respective target molecules are described. The methods involve contacting the candidate mixture with the target molecule, allowing the formation of nucleic acid-target complexes to occur, and performing a slow off-rate enrichment process wherein nucleic acid-target complexes with fast dissociation rates will dissociate and not reform, while complexes with slow dissociation rates will remain intact. Additionally, the methods include the use of modified nucleotides in the production of candidate nucleic acid mixtures to generate aptamers with improved off-rate performance.

A variation of this assay employs aptamers that include photoreactive functional groups that enable the aptamers to covalently bind or “photocrosslink” their target molecules. See, e.g., U.S. Pat. No. 6,544,776 entitled “Nucleic Acid Ligand Diagnostic Biochip”. These photoreactive aptamers are also referred to as photoaptamers. See, e.g., U.S. Pat. No. 5,763,177, U.S. Pat. No. 6,001,577, and U.S. Pat. No. 6,291,184, each of which is entitled “Systematic Evolution of Nucleic Acid Ligands by Exponential Enrichment: Photoselection of Nucleic Acid Ligands and Solution SELEX”; see also, e.g., U.S. Pat. No. 6,458,539, entitled “Photoselection of Nucleic Acid Ligands”. After the microarray is contacted with the sample and the photoaptamers have had an opportunity to bind to their target molecules, the photoaptamers are photoactivated, and the solid support is washed to remove any non-specifically bound molecules. Harsh wash conditions may be used, since target molecules that are bound to the photoaptamers are generally not removed, due to the covalent bonds created by the photoactivated functional group(s) on the photoaptamers. In this manner, the assay enables the detection of a biomarker value corresponding to a biomarker in the test sample.

In both of these assay formats, the aptamers are immobilized on the solid support prior to being contacted with the sample. Under certain circumstances, however, immobilization of the aptamers prior to contact with the sample may not provide an optimal assay. For example, pre-immobilization of the aptamers may result in inefficient mixing of the aptamers with the target molecules on the surface of the solid support, perhaps leading to lengthy reaction times and, therefore, extended incubation periods to permit efficient binding of the aptamers to their target molecules. Further, when photoaptamers are employed in the assay and depending upon the material utilized as a solid support, the solid support may tend to scatter or absorb the light used to effect the formation of covalent bonds between the photoaptamers and their target molecules. Moreover, depending upon the method employed, detection of target molecules bound to their aptamers can be subject to imprecision, since the surface of the solid support may also be exposed to and affected by any labeling agents that are used. Finally, immobilization of the aptamers on the solid support generally involves an aptamer-preparation step (i.e., the immobilization) prior to exposure of the aptamers to the sample, and this preparation step may affect the activity or functionality of the aptamers.

Aptamer assays that permit an aptamer to capture its target in solution and then employ separation steps that are designed to remove specific components of the aptamer-target mixture prior to detection have also been described (see U.S. Patent Application Publication 2009/0042206, entitled “Multiplexed Analyses of Test Samples”). The described aptamer assay methods enable the detection and quantification of a non-nucleic acid target (e.g., a protein target) in a test sample by detecting and quantifying a nucleic acid (i.e., an aptamer). The described methods create a nucleic acid surrogate (i.e, the aptamer) for detecting and quantifying a non-nucleic acid target, thus allowing the wide variety of nucleic acid technologies, including amplification, to be applied to a broader range of desired targets, including protein targets.

Aptamers can be constructed to facilitate the separation of the assay components from an aptamer biomarker complex (or photoaptamer biomarker covalent complex) and permit isolation of the aptamer for detection and/or quantification. In one embodiment, these constructs can include a cleavable or releasable element within the aptamer sequence. In other embodiments, additional functionality can be introduced into the aptamer, for example, a labeled or detectable component, a spacer component, or a specific binding tag or immobilization element. For example, the aptamer can include a tag connected to the aptamer via a cleavable moiety, a label, a spacer component separating the label, and the cleavable moiety. In one embodiment, a cleavable element is a photocleavable linker. The photocleavable linker can be attached to a biotin moiety and a spacer section, can include an NHS group for derivatization of amines, and can be used to introduce a biotin group to an aptamer, thereby allowing for the release of the aptamer later in an assay method.

Homogenous assays, done with all assay components in solution, do not require separation of sample and reagents prior to the detection of signal. These methods are rapid and easy to use. These methods generate signal based on a molecular capture or binding reagent that reacts with its specific target. For NSCLC, the molecular capture reagents would be an aptamer or an antibody or the like and the specific target would be a NSCLC biomarker of Table 1.

In one embodiment, a method for signal generation takes advantage of anisotropy signal change due to the interaction of a fluorophore-labeled capture reagent with its specific biomarker target. When the labeled capture reacts with its target, the increased molecular weight causes the rotational motion of the fluorophore attached to the complex to become much slower changing the anisotropy value. By monitoring the anisotropy change, binding events may be used to quantitatively measure the biomarkers in solutions. Other methods include fluorescence polarization assays, molecular beacon methods, time resolved fluorescence quenching, chemiluminescence, fluorescence resonance energy transfer, and the like.

An exemplary solution-based aptamer assay that can be used to detect a biomarker value corresponding to a biomarker in a biological sample includes the following: (a) preparing a mixture by contacting the biological sample with an aptamer that includes a first tag and has a specific affinity for the biomarker, wherein an aptamer affinity complex is formed when the biomarker is present in the sample; (b) exposing the mixture to a first solid support including a first capture element, and allowing the first tag to associate with the first capture element; (c) removing any components of the mixture not associated with the first solid support; (d) attaching a second tag to the biomarker component of the aptamer affinity complex; (e) releasing the aptamer affinity complex from the first solid support; (f) exposing the released aptamer affinity complex to a second solid support that includes a second capture element and allowing the second tag to associate with the second capture element; (g) removing any non-complexed aptamer from the mixture by partitioning the non-complexed aptamer from the aptamer affinity complex; (h) eluting the aptamer from the solid support; and (i) detecting the biomarker by detecting the aptamer component of the aptamer affinity complex.

Any means known in the art can be used to detect a biomarker value by detecting the aptamer component of an aptamer affinity complex. A number of different detection methods can be used to detect the aptamer component of an affinity complex, such as, for example, hybridization assays, mass spectroscopy, or QPCR. In some embodiments, nucleic acid sequencing methods can be used to detect the aptamer component of an aptamer affinity complex and thereby detect a biomarker value. Briefly, a test sample can be subjected to any kind of nucleic acid sequencing method to identify and quantify the sequence or sequences of one or more aptamers present in the test sample. In some embodiments, the sequence includes the entire aptamer molecule or any portion of the molecule that may be used to uniquely identify the molecule. In other embodiments, the identifying sequencing is a specific sequence added to the aptamer; such sequences are often referred to as “tags,” “barcodes,” or “zipcodes.” In some embodiments, the sequencing method includes enzymatic steps to amplify the aptamer sequence or to convert any kind of nucleic acid, including RNA and DNA that contain chemical modifications to any position, to any other kind of nucleic acid appropriate for sequencing.

In some embodiments, the sequencing method includes one or more cloning steps. In other embodiments the sequencing method includes a direct sequencing method without cloning.

In some embodiments, the sequencing method includes a directed approach with specific primers that target one or more aptamers in the test sample. In other embodiments, the sequencing method includes a shotgun approach that targets all aptamers in the test sample.

In some embodiments, the sequencing method includes enzymatic steps to amplify the molecule targeted for sequencing. In other embodiments, the sequencing method directly sequences single molecules. An exemplary nucleic acid sequencing-based method that can be used to detect a biomarker value corresponding to a biomarker in a biological sample includes the following: (a) converting a mixture of aptamers that contain chemically modified nucleotides to unmodified nucleic acids with an enzymatic step; (b) shotgun sequencing the resulting unmodified nucleic acids with a massively parallel sequencing platform such as, for example, the 454 Sequencing System (454 Life Sciences/Roche), the Illumina Sequencing System (Illumina), the ABI SOLID Sequencing System (Applied Biosystems), the HeliScope Single Molecule Sequencer (Helicon Biosciences), or the Pacific Biosciences Real Time Single-Molecule Sequencing System (Pacific BioSciences) or the Polonator G Sequencing System (Dover Systems); and (c) identifying and quantifying the aptamers present in the mixture by specific sequence and sequence count.

Determination of Biomarker Values Using Immunoassays

Immunoassay methods are based on the reaction of an antibody to its corresponding target or analyte and can detect the analyte in a sample depending on the specific assay format. To improve specificity and sensitivity of an assay method based on immuno-reactivity, monoclonal antibodies are often used because of their specific epitope recognition. Polyclonal antibodies have also been successfully used in various immunoassays because of their increased affinity for the target as compared to monoclonal antibodies. Immunoassays have been designed for use with a wide range of biological sample matrices. Immunoassay formats have been designed to provide qualitative, semi-quantitative, and quantitative results.

Quantitative results are generated through the use of a standard curve created with known concentrations of the specific analyte to be detected. The response or signal from an unknown sample is plotted onto the standard curve, and a quantity or value corresponding to the target in the unknown sample is established.

Numerous immunoassay formats have been designed. ELISA or EIA can be quantitative for the detection of an analyte. This method relies on attachment of a label to either the analyte or the antibody and the label component includes, either directly or indirectly, an enzyme. ELISA tests may be formatted for direct, indirect, competitive, or sandwich detection of the analyte. Other methods rely on labels such as, for example, radioisotopes (1125) or fluorescence. Additional techniques include, for example, agglutination, nephelometry, turbidimetry, Western blot, immunoprecipitation, immunocytochemistry, immunohistochemistry, flow cytometry, serology, Luminex assay, and others (see ImmunoAssay: A Practical Guide, edited by Brian Law, published by Taylor & Francis, Ltd., 2005 edition).

Exemplary assay formats include enzyme-linked immunosorbent assay (ELISA), radioimmunoassay, fluorescent, chemiluminescence, and fluorescence resonance energy transfer (FRET) or time resolved-FRET (TR-FRET) immunoassays. Examples of procedures for detecting biomarkers include biomarker immunoprecipitation followed by quantitative methods that allow size and peptide level discrimination, such as gel electrophoresis, capillary electrophoresis, planar electrochromatography, and the like.

Methods of detecting and/or quantifying a detectable label or signal generating material depend on the nature of the label. The products of reactions catalyzed by appropriate enzymes (where the detectable label is an enzyme; see above) can be, without limitation, fluorescent, luminescent, or radioactive or they may absorb visible or ultraviolet light. Examples of detectors suitable for detecting such detectable labels include, without limitation, x-ray film, radioactivity counters, scintillation counters, spectrophotometers, colorimeters, fluorometers, luminometers, and densitometers.

Any of the methods for detection can be performed in any format that allows for any suitable preparation, processing, and analysis of the reactions. This can be, for example, in multi-well assay plates (e.g., 96 wells or 384 wells) or using any suitable array or microarray. Stock solutions for various agents can be made manually or robotically, and all subsequent pipetting, diluting, mixing, distribution, washing, incubating, sample readout, data collection and analysis can be done robotically using commercially available analysis software, robotics, and detection instrumentation capable of detecting a detectable label.

Determination of Biomarker Values Using Gene Expression Profiling

Measuring mRNA in a biological sample may be used as a surrogate for detection of the level of the corresponding protein in the biological sample. Thus, any of the biomarkers or biomarker panels described herein can also be detected by detecting the appropriate RNA.

mRNA expression levels are measured by reverse transcription quantitative polymerase chain reaction (RT-PCR followed with qPCR). RT-PCR is used to create a cDNA from the mRNA. The cDNA may be used in a qPCR assay to produce fluorescence as the DNA amplification process progresses. By comparison to a standard curve, qPCR can produce an absolute measurement such as number of copies of mRNA per cell. Northern blots, microarrays, Invader assays, and RT-PCR combined with capillary electrophoresis have all been used to measure expression levels of mRNA in a sample. See Gene Expression Profiling: Methods and Protocols, Richard A. Shimkets, editor, Humana Press, 2004.

miRNA molecules are small RNAs that are non-coding but may regulate gene expression. Any of the methods suited to the measurement of mRNA expression levels can also be used for the corresponding miRNA. Recently many laboratories have investigated the use of miRNAs as biomarkers for disease. Many diseases involve wide-spread transcriptional regulation, and it is not surprising that miRNAs might find a role as biomarkers. The connection between miRNA concentrations and disease is often even less clear than the connections between protein levels and disease, yet the value of miRNA biomarkers might be substantial. Of course, as with any RNA expressed differentially during disease, the problems facing the development of an in vitro diagnostic product will include the requirement that the miRNAs survive in the diseased cell and are easily extracted for analysis, or that the miRNAs are released into blood or other matrices where they must survive long enough to be measured. Protein biomarkers have similar requirements, although many potential protein biomarkers are secreted intentionally at the site of pathology and function, during disease, in a paracrine fashion. Many potential protein biomarkers are designed to function outside the cells within which those proteins are synthesized.

Detection of Biomarkers Using In Vivo Molecular Imaging Technologies

Any of the described biomarkers (see Table 1) may also be used in molecular imaging tests. For example, an imaging agent can be coupled to any of the described biomarkers, which can be used to aid in NSCLC diagnosis, to monitor disease progression/remission or metastasis, to monitor for disease recurrence, or to monitor response to therapy, among other uses.

In vivo imaging technologies provide non-invasive methods for determining the state of a particular disease in the body of an individual. For example, entire portions of the body, or even the entire body, may be viewed as a three dimensional image, thereby providing valuable information concerning morphology and structures in the body. Such technologies may be combined with the detection of the biomarkers described herein to provide information concerning the cancer status, in particular the NSCLC status, of an individual.

The use of in vivo molecular imaging technologies is expanding due to various advances in technology. These advances include the development of new contrast agents or labels, such as radiolabels and/or fluorescent labels, which can provide strong signals within the body; and the development of powerful new imaging technology, which can detect and analyze these signals from outside the body, with sufficient sensitivity and accuracy to provide useful information. The contrast agent can be visualized in an appropriate imaging system, thereby providing an image of the portion or portions of the body in which the contrast agent is located. The contrast agent may be bound to or associated with a capture reagent, such as an aptamer or an antibody, for example, and/or with a peptide or protein, or an oligonucleotide (for example, for the detection of gene expression), or a complex containing any of these with one or more macromolecules and/or other particulate forms.

The contrast agent may also feature a radioactive atom that is useful in imaging. Suitable radioactive atoms include technetium-99m or iodine-123 for scintigraphic studies. Other readily detectable moieties include, for example, spin labels for magnetic resonance imaging (MRI) such as, for example, iodine-123 again, iodine-131, indium-111, fluorine-19, carbon-13, nitrogen-15, oxygen-17, gadolinium, manganese or iron. Such labels are well known in the art and could easily be selected by one of ordinary skill in the art.

Standard imaging techniques include but are not limited to magnetic resonance imaging, computed tomography scanning, positron emission tomography (PET), single photon emission computed tomography (SPECT), and the like. For diagnostic in vivo imaging, the type of detection instrument available is a major factor in selecting a given contrast agent, such as a given radionuclide and the particular biomarker that it is used to target (protein, mRNA, and the like). The radionuclide chosen typically has a type of decay that is detectable by a given type of instrument. Also, when selecting a radionuclide for in vivo diagnosis, its half-life should be long enough to enable detection at the time of maximum uptake by the target tissue but short enough that deleterious radiation of the host is minimized.

Exemplary imaging techniques include but are not limited to PET and SPECT, which are imaging techniques in which a radionuclide is synthetically or locally administered to an individual. The subsequent uptake of the radiotracer is measured over time and used to obtain information about the targeted tissue and the biomarker. Because of the high-energy (gamma-ray) emissions of the specific isotopes employed and the sensitivity and sophistication of the instruments used to detect them, the two-dimensional distribution of radioactivity may be inferred from outside of the body.

Commonly used positron-emitting nuclides in PET include, for example, carbon-11, nitrogen-13, oxygen-15, and fluorine-18. Isotopes that decay by electron capture and/or gamma-emission are used in SPECT and include, for example iodine-123 and technetium-99m. An exemplary method for labeling amino acids with technetium-99m is the reduction of pertechnetate ion in the presence of a chelating precursor to form the labile technetium-99m-precursor complex, which, in turn, reacts with the metal binding group of a bifunctionally modified chemotactic peptide to form a technetium-99m-chemotactic peptide conjugate.

Antibodies are frequently used for such in vivo imaging diagnostic methods. The preparation and use of antibodies for in vivo diagnosis is well known in the art. Labeled antibodies which specifically bind any of the biomarkers in Table 1 can be injected into an individual suspected of having a certain type of cancer (e.g., NSCLC), detectable according to the particular biomarker used, for the purpose of diagnosing or evaluating the disease status of the individual. The label used will be selected in accordance with the imaging modality to be used, as previously described. Localization of the label permits determination of the spread of the cancer. The amount of label within an organ or tissue also allows determination of the presence or absence of cancer in that organ or tissue.

Similarly, aptamers may be used for such in vivo imaging diagnostic methods. For example, an aptamer that was used to identify a particular biomarker described in Table 1 (and therefore binds specifically to that particular biomarker) may be appropriately labeled and injected into an individual suspected of having NSCLC, detectable according to the particular biomarker, for the purpose of diagnosing or evaluating the NSCLC status of the individual. The label used will be selected in accordance with the imaging modality to be used, as previously described. Localization of the label permits determination of the spread of the cancer. The amount of label within an organ or tissue also allows determination of the presence or absence of cancer in that organ or tissue. Aptamer-directed imaging agents could have unique and advantageous characteristics relating to tissue penetration, tissue distribution, kinetics, elimination, potency, and selectivity as compared to other imaging agents.

Such techniques may also optionally be performed with labeled oligonucleotides, for example, for detection of gene expression through imaging with antisense oligonucleotides. These methods are used for in situ hybridization, for example, with fluorescent molecules or radionuclides as the label. Other methods for detection of gene expression include, for example, detection of the activity of a reporter gene.

Another general type of imaging technology is optical imaging, in which fluorescent signals within the subject are detected by an optical device that is external to the subject. These signals may be due to actual fluorescence and/or to bioluminescence. Improvements in the sensitivity of optical detection devices have increased the usefulness of optical imaging for in vivo diagnostic assays.

The use of in vivo molecular biomarker imaging is increasing, including for clinical trials, for example, to more rapidly measure clinical efficacy in trials for new cancer therapies and/or to avoid prolonged treatment with a placebo for those diseases, such as multiple sclerosis, in which such prolonged treatment may be considered to be ethically questionable.

For a review of other techniques, see N. Blow, Nature Methods, 6, 465-469, 2009.

Determination of Biomarker Values Using Histology/Cytology Methods

For evaluation of NSCLC, a variety of tissue samples may be used in histological or cytological methods. Sample selection depends on the primary tumor location and sites of metastases. For example, endo- and trans-bronchial biopsies, fine needle aspirates, cutting needles, and core biopsies can be used for histology. Bronchial washing and brushing, pleural aspiration, pleural fluid, and sputum, can be used for cyotology. While cytological analysis is still used in the diagnosis of NSCLC, histological methods are known to provide better sensitivity for the detection of cancer. Any of the biomarkers identified herein that were shown to be up-regulated (Table 1) in the individuals with NSCLC can be used to stain a histological specimen as an indication of disease.

In one embodiment, one or more capture reagents specific to the corresponding biomarker(s) are used in a cytological evaluation of a lung tissue cell sample and may include one or more of the following: collecting a cell sample, fixing the cell sample, dehydrating, clearing, immobilizing the cell sample on a microscope slide, permeabilizing the cell sample, treating for analyte retrieval, staining, destaining, washing, blocking, and reacting with one or more capture reagent/s in a buffered solution. In another embodiment, the cell sample is produced from a cell block.

In another embodiment, one or more capture reagent(s) specific to the corresponding biomarker(s) are used in a histological evaluation of a lung tissue sample and may include one or more of the following: collecting a tissue specimen, fixing the tissue sample, dehydrating, clearing, immobilizing the tissue sample on a microscope slide, permeabilizing the tissue sample, treating for analyte retrieval, staining, destaining, washing, blocking, rehydrating, and reacting with capture reagent(s) in a buffered solution. In another embodiment, fixing and dehydrating are replaced with freezing.

In another embodiment, the one or more aptamer(s) specific to the corresponding biomarker(s) are reacted with the histological or cytological sample and can serve as the nucleic acid target in a nucleic acid amplification method. Suitable nucleic acid amplification methods include, for example, PCR, q-beta replicase, rolling circle amplification, strand displacement, helicase dependent amplification, loop mediated isothermal amplification, ligase chain reaction, and restriction and circularization aided rolling circle amplification.

In one embodiment, the one or more capture reagent(s) specific to the corresponding biomarkers for use in the histological or cytological evaluation are mixed in a buffered solution that can include any of the following: blocking materials, competitors, detergents, stabilizers, carrier nucleic acid, polyanionic materials, etc.

A “cytology protocol” generally includes sample collection, sample fixation, sample immobilization, and staining. “Cell preparation” can include several processing steps after sample collection, including the use of one or more slow off-rate aptamers for the staining of the prepared cells.

Sample collection can include directly placing the sample in an untreated transport container, placing the sample in a transport container containing some type of media, or placing the sample directly onto a slide (immobilization) without any treatment or fixation.

Sample immobilization can be improved by applying a portion of the collected specimen to a glass slide that is treated with polylysine, gelatin, or a silane. Slides can be prepared by smearing a thin and even layer of cells across the slide. Care is generally taken to minimize mechanical distortion and drying artifacts. Liquid specimens can be processed in a cell block method. Or, alternatively, liquid specimens can be mixed 1:1 with the fixative solution for about 10 minutes at room temperature.

Cell blocks can be prepared from residual effusions, sputum, urine sediments, gastrointestinal fluids, pulmonary fluids, cell scraping, or fine needle aspirates. Cells are concentrated or packed by centrifugation or membrane filtration. A number of methods for cell block preparation have been developed. Representative procedures include the fixed sediment, bacterial agar, or membrane filtration methods. In the fixed sediment method, the cell sediment is mixed with a fixative like Bouins, picric acid, or buffered formalin and then the mixture is centrifuged to pellet the fixed cells. The supernatant is removed, drying the cell pellet as completely as possible. The pellet is collected and wrapped in lens paper and then placed in a tissue cassette. The tissue cassette is placed in a jar with additional fixative and processed as a tissue sample. Agar method is very similar but the pellet is removed and dried on paper towel and then cut in half. The cut side is placed in a drop of melted agar on a glass slide and then the pellet is covered with agar making sure that no bubbles form in the agar. The agar is allowed to harden and then any excess agar is trimmed away. This is placed in a tissue cassette and the tissue process completed. Alternatively, the pellet may be directly suspended in 2% liquid agar at 65° C. and the sample centrifuged. The agar cell pellet is allowed to solidify for an hour at 4° C. The solid agar may be removed from the centrifuge tube and sliced in half. The agar is wrapped in filter paper and then the tissue cassette. Processing from this point forward is as described above. Centrifugation can be replaced in any these procedures with membrane filtration. Any of these processes may be used to generate a “cell block sample”.

Cell blocks can be prepared using specialized resin including Lowicryl resins, LR White, LR Gold, Unicryl, and MonoStep. These resins have low viscosity and can be polymerized at low temperatures and with ultra violet (UV) light. The embedding process relies on progressively cooling the sample during dehydration, transferring the sample to the resin, and polymerizing a block at the final low temperature at the appropriate UV wavelength.

Cell block sections can be stained with hematoxylin-eosin for cytomorphological examination while additional sections are used for examination for specific markers.

Whether the process is cytologoical or histological, the sample may be fixed prior to additional processing to prevent sample degradation. This process is called “fixation” and describes a wide range of materials and procedures that may be used interchangeably. The sample fixation protocol and reagents are best selected empirically based on the targets to be detected and the specific cell/tissue type to be analyzed. Sample fixation relies on reagents such as ethanol, polyethylene glycol, methanol, formalin, or isopropanol. The samples should be fixed as soon after collection and affixation to the slide as possible. However, the fixative selected can introduce structural changes into various molecular targets making their subsequent detection more difficult. The fixation and immobilization processes and their sequence can modify the appearance of the cell and these changes must be anticipated and recognized by the cytotechnologist. Fixatives can cause shrinkage of certain cell types and cause the cytoplasm to appear granular or reticular. Many fixatives function by crosslinking cellular components. This can damage or modify specific epitopes, generate new epitopes, cause molecular associations, and reduce membrane permeability. Formalin fixation is one of the most common cytological/histological approaches. Formalin forms methyl bridges between neighboring proteins or within proteins. Precipitation or coagulation is also used for fixation and ethanol is frequently used in this type of fixation. A combination of crosslinking and precipitation can also be used for fixation. A strong fixation process is best at preserving morphological information while a weaker fixation process is best for the preservation of molecular targets.

A representative fixative is 50% absolute ethanol, 2 mM polyethylene glycol (PEG), 1.85% formaldehyde. Variations on this formulation include ethanol (50% to 95%), methanol (20%-50%), and formalin (formaldehyde) only. Another common fixative is 2% PEG 1500, 50% ethanol, and 3% methanol. Slides are place in the fixative for about 10 to 15 minutes at room temperature and then removed and allowed to dry. Once slides are fixed they can be rinsed with a buffered solution like PBS.

A wide range of dyes can be used to differentially highlight and contrast or “stain” cellular, sub-cellular, and tissue features or morphological structures. Hematoylin is used to stain nuclei a blue or black color. Orange G-6 and Eosin Azure both stain the cell's cytoplasm. Orange G stains keratin and glycogen containing cells yellow. Eosin Y is used to stain nucleoli, cilia, red blood cells, and superficial epithelial squamous cells. Romanowsky stains are used for air dried slides and are useful in enhancing pleomorphism and distinguishing extracellular from intracytoplasmic material.

The staining process can include a treatment to increase the permeability of the cells to the stain. Treatment of the cells with a detergent can be used to increase permeability. To increase cell and tissue permeability, fixed samples can be further treated with solvents, saponins, or non-ionic detergents. Enzymatic digestion can also improve the accessibility of specific targets in a tissue sample.

After staining, the sample is dehydrated using a succession of alcohol rinses with increasing alcohol concentration. The final wash is done with xylene or a xylene substitute, such as a citrus terpene, that has a refractive index close to that of the coverslip to be applied to the slide. This final step is referred to as clearing. Once the sample is dehydrated and cleared, a mounting medium is applied. The mounting medium is selected to have a refractive index close to the glass and is capable of bonding the coverslip to the slide. It will also inhibit the additional drying, shrinking, or fading of the cell sample.

Regardless of the stains or processing used, the final evaluation of the lung cytological specimen is made by some type of microscopy to permit a visual inspection of the morphology and a determination of the marker's presence or absence. Exemplary microscopic methods include brightfield, phase contrast, fluorescence, and differential interference contrast.

If secondary tests are required on the sample after examination, the coverslip may be removed and the slide destained. Destaining involves using the original solvent systems used in staining the slide originally without the added dye and in a reverse order to the original staining procedure. Destaining may also be completed by soaking the slide in an acid alcohol until the cells are colorless. Once colorless the slides are rinsed well in a water bath and the second staining procedure applied.

In addition, specific molecular differentiation may be possible in conjunction with the cellular morphological analysis through the use of specific molecular reagents such as antibodies or nucleic acid probes or aptamers. This improves the accuracy of diagnostic cytology. Micro-dissection can be used to isolate a subset of cells for additional evaluation, in particular, for genetic evaluation of abnormal chromosomes, gene expression, or mutations.

Preparation of a tissue sample for histological evaluation involves fixation, dehydration, infiltration, embedding, and sectioning. The fixation reagents used in histology are very similar or identical to those used in cytology and have the same issues of preserving morphological features at the expense of molecular ones such as individual proteins. Time can be saved if the tissue sample is not fixed and dehydrated but instead is frozen and then sectioned while frozen. This is a more gentle processing procedure and can preserve more individual markers. However, freezing is not acceptable for long term storage of a tissue sample as subcellular information is lost due to the introduction of ice crystals. Ice in the frozen tissue sample also prevents the sectioning process from producing a very thin slice and thus some microscopic resolution and imaging of subcellular structures can be lost. In addition to formalin fixation, osmium tetroxide is used to fix and stain phospholipids (membranes).

Dehydration of tissues is accomplished with successive washes of increasing alcohol concentration. Clearing employs a material that is miscible with alcohol and the embedding material and involves a stepwise process starting at 50:50 alcohol:clearing reagent and then 100% clearing agent (xylene or xylene substitute). Infiltration involves incubating the tissue with a liquid form of the embedding agent (warm wax, nitrocellulose solution) first at 50:50 embedding agent: clearing agent and the 100% embedding agent. Embedding is completed by placing the tissue in a mold or cassette and filling with melted embedding agent such as wax, agar, or gelatin. The embedding agent is allowed to harden. The hardened tissue sample may then be sliced into thin section for staining and subsequent examination.

Prior to staining, the tissue section is dewaxed and rehydrated. Xylene is used to dewax the section, one or more changes of xylene may be used, and the tissue is rehydrated by successive washes in alcohol of decreasing concentration. Prior to dewax, the tissue section may be heat immobilized to a glass slide at about 80° C. for about 20 minutes.

Laser capture micro-dissection allows the isolation of a subset of cells for further analysis from a tissue section.

As in cytology, to enhance the visualization of the microscopic features, the tissue section or slice can be stained with a variety of stains. A large menu of commercially available stains can be used to enhance or identify specific features.

To further increase the interaction of molecular reagents with cytological/histological samples, a number of techniques for “analyte retrieval” have been developed. The first such technique uses high temperature heating of a fixed sample. This method is also referred to as heat-induced epitope retrieval or HIER. A variety of heating techniques have been used, including steam heating, microwaving, autoclaving, water baths, and pressure cooking or a combination of these methods of heating. Analyte retrieval solutions include, for example, water, citrate, and normal saline buffers. The key to analyte retrieval is the time at high temperature but lower temperatures for longer times have also been successfully used. Another key to analyte retrieval is the pH of the heating solution. Low pH has been found to provide the best immunostaining but also gives rise to backgrounds that frequently require the use of a second tissue section as a negative control. The most consistent benefit (increased immunostaining without increase in background) is generally obtained with a high pH solution regardless of the buffer composition. The analyte retrieval process for a specific target is empirically optimized for the target using heat, time, pH, and buffer composition as variables for process optimization. Using the microwave analyte retrieval method allows for sequential staining of different targets with antibody reagents. But the time required to achieve antibody and enzyme complexes between staining steps has also been shown to degrade cell membrane analytes. Microwave heating methods have improved in situ hybridization methods as well.

To initiate the analyte retrieval process, the section is first dewaxed and hydrated. The slide is then placed in 10 mM sodium citrate buffer pH 6.0 in a dish or jar. A representative procedure uses an 1100 W microwave and microwaves the slide at 100% power for 2 minutes followed by microwaving the slides using 20% power for 18 minutes after checking to be sure the slide remains covered in liquid. The slide is then allowed to cool in the uncovered container and then rinsed with distilled water. HIER may be used in combination with an enzymatic digestion to improve the reactivity of the target to immunochemical reagents.

One such enzymatic digestion protocol uses proteinase K. A 20 g/ml concentration of proteinase K is prepared in 50 mM Tris Base, 1 mM EDTA, 0.5% Triton X-100, pH 8.0 buffer. The process first involves dewaxing sections in 2 changes of xylene, 5 minutes each. Then the sample is hydrated in 2 changes of 100% ethanol for 3 minutes each, 95% and 80% ethanol for 1 minute each, and then rinsed in distilled water. Sections are covered with Proteinase K working solution and incubated 10-20 minutes at 37° C. in humidified chamber (optimal incubation time may vary depending on tissue type and degree of fixation). The sections are cooled at room temperature for 10 minutes and then rinsed in PBS Tween 20 for 2×2 min. If desired, sections can be blocked to eliminate potential interference from endogenous compounds and enzymes. The section is then incubated with primary antibody at appropriate dilution in primary antibody dilution buffer for 1 hour at room temperature or overnight at 4° C. The section is then rinsed with PBS Tween 20 for 2×2 min. Additional blocking can be performed, if required for the specific application, followed by additional rinsing with PBS Tween 20 for 3×2 min and then finally the immunostaining protocol completed.

A simple treatment with 1% SDS at room temperature has also been demonstrated to improve immunohistochemical staining. Analyte retrieval methods have been applied to slide mounted sections as well as free floating sections. Another treatment option is to place the slide in a jar containing citric acid and 0.1 Nonident P40 at pH 6.0 and heating to 95° C. The slide is then washed with a buffer solution like PBS.

For immunological staining of tissues it may be useful to block non-specific association of the antibody with tissue proteins by soaking the section in a protein solution like serum or non-fat dry milk.

Blocking reactions may include the need to reduce the level of endogenous biotin; eliminate endogenous charge effects; inactivate endogenous nucleases; and/or inactivate endogenous enzymes like peroxidase and alkaline phosphatase. Endogenous nucleases may be inactivated by degradation with proteinase K, by heat treatment, use of a chelating agent such as EDTA or EGTA, the introduction of carrier DNA or RNA, treatment with a chaotrope such as urea, thiourea, guanidine hydrochloride, guanidine thiocyanate, lithium perchlorate, etc, or diethyl pyrocarbonate. Alkaline phosphatase may be inactivated by treated with 0.1N HCl for 5 minutes at room temperature or treatment with 1 mM levamisole. Peroxidase activity may be eliminated by treatment with 0.03% hydrogen peroxide. Endogenous biotin may be blocked by soaking the slide or section in an avidin (streptavidin, neutravidin may be substituted) solution for at least 15 minutes at room temperature. The slide or section is then washed for at least 10 minutes in buffer. This may be repeated at least three times. Then the slide or section is soaked in a biotin solution for 10 minutes. This may be repeated at least three times with a fresh biotin solution each time. The buffer wash procedure is repeated. Blocking protocols should be minimized to prevent damaging either the cell or tissue structure or the target or targets of interest but one or more of these protocols could be combined to “block” a slide or section prior to reaction with one or more slow off-rate aptamers. See Basic Medical Histology: the Biology of Cells, Tissues and Organs, authored by Richard G. Kessel, Oxford University Press, 1998.

Determination of Biomarker Values Using Mass Spectrometry Methods

A variety of configurations of mass spectrometers can be used to detect biomarker values. Several types of mass spectrometers are available or can be produced with various configurations. In general, a mass spectrometer has the following major components: a sample inlet, an ion source, a mass analyzer, a detector, a vacuum system, and instrument-control system, and a data system. Difference in the sample inlet, ion source, and mass analyzer generally define the type of instrument and its capabilities. For example, an inlet can be a capillary-column liquid chromatography source or can be a direct probe or stage such as used in matrix-assisted laser desorption. Common ion sources are, for example, electrospray, including nanospray and microspray or matrix-assisted laser desorption. Common mass analyzers include a quadrupole mass filter, ion trap mass analyzer and time-of-flight mass analyzer. Additional mass spectrometry methods are well known in the art (see Burlingame et al. Anal. Chem. 70:647 R-716R (1998); Kinter and Sherman, New York (2000)).

Protein biomarkers and biomarker values can be detected and measured by any of the following: electrospray ionization mass spectrometry (ESI-MS), ESI-MS/MS, ESIMS/(MS)n, matrix-assisted laser desorption ionization time-of-flight mass spectrometry (MALDI-TOF-MS), surface-enhanced laser desorption/ionization time-of-flight mass spectrometry (SELDI-TOF-MS), desorption/ionization on silicon (DIOS), secondary ion mass spectrometry (SIMS), quadrupole time-of-flight (Q-TOF), tandem time-of-flight (TOF/TOF) technology, called ultraflex III TOF/TOF, atmospheric pressure chemical ionization mass spectrometry (APCI-MS), APCI-MS/MS, APCI-(MS)N, atmospheric pressure photoionization mass spectrometry (APPI-MS), APPI-MS/MS, and APPI-(MS)N, quadrupole mass spectrometry, Fourier transform mass spectrometry (FTMS), quantitative mass spectrometry, and ion trap mass spectrometry.

Sample preparation strategies are used to label and enrich samples before mass spectroscopic characterization of protein biomarkers and determination biomarker values. Labeling methods include but are not limited to isobaric tag for relative and absolute quantitation (iTRAQ) and stable isotope labeling with amino acids in cell culture (SILAC). Capture reagents used to selectively enrich samples for candidate biomarker proteins prior to mass spectroscopic analysis include but are not limited to aptamers, antibodies, nucleic acid probes, chimeras, small molecules, an F(ab′)2 fragment, a single chain antibody fragment, an Fv fragment, a single chain Fv fragment, a nucleic acid, a lectin, a ligand-binding receptor, affybodies, nanobodies, ankyrins, domain antibodies, alternative antibody scaffolds (e.g. diabodies etc) imprinted polymers, avimers, peptidomimetics, peptoids, peptide nucleic acids, threose nucleic acid, a hormone receptor, a cytokine receptor, and synthetic receptors, and modifications and fragments of these.

Determination of Biomarker Values Using a Proximity Ligation Assay

A proximity ligation assay can be used to determine biomarker values. Briefly, a test sample is contacted with a pair of affinity probes that may be a pair of antibodies or a pair of aptamers, with each member of the pair extended with an oligonucleotide. The targets for the pair of affinity probes may be two distinct determinates on one protein or one determinate on each of two different proteins, which may exist as homo- or heteromultimeric complexes. When probes bind to the target determinates, the free ends of the oligonucleotide extensions are brought into sufficiently close proximity to hybridize together. The hybridization of the oligonucleotide extensions is facilitated by a common connector oligonucleotide which serves to bridge together the oligonucleotide extensions when they are positioned in sufficient proximity. Once the oligonucleotide extensions of the probes are hybridized, the ends of the extensions are joined together by enzymatic DNA ligation.

Each oligonucleotide extension comprises a primer site for PCR amplification. Once the oligonucleotide extensions are ligated together, the oligonucleotides form a continuous DNA sequence which, through PCR amplification, reveals information regarding the identity and amount of the target protein, as well as, information regarding protein-protein interactions where the target determinates are on two different proteins. Proximity ligation can provide a highly sensitive and specific assay for real-time protein concentration and interaction information through use of real-time PCR. Probes that do not bind the determinates of interest do not have the corresponding oligonucleotide extensions brought into proximity and no ligation or PCR amplification can proceed, resulting in no signal being produced.

The foregoing assays enable the detection of biomarker values that are useful in methods for diagnosing NSCLC, where the methods comprise detecting, in a biological sample from an individual, at least N biomarker values that each correspond to a biomarker selected from the group consisting of the biomarkers provided in Table 1, wherein a classification, as described in detail below, using the biomarker values indicates whether the individual has NSCLC. While certain of the described NSCLC biomarkers are useful alone for detecting and diagnosing NSCLC, methods are also described herein for the grouping of multiple subsets of the NSCLC biomarkers that are each useful as a panel of three or more biomarkers. Thus, various embodiments of the instant application provide combinations comprising N biomarkers, wherein N is at least three biomarkers. In other embodiments, N is selected to be any number from 2-59 biomarkers. It will be appreciated that N can be selected to be any number from any of the above described ranges, as well as similar, but higher order, ranges. In accordance with any of the methods described herein, biomarker values can be detected and classified individually or they can be detected and classified collectively, as for example in a multiplex assay format.

In another aspect, methods are provided for detecting an absence of NSCLC, the methods comprising detecting, in a biological sample from an individual, at least N biomarker values that each correspond to a biomarker selected from the group consisting of the biomarkers provided in Table 1, wherein a classification, as described in detail below, of the biomarker values indicates an absence of NSCLC in the individual. While certain of the described NSCLC biomarkers are useful alone for detecting and diagnosing the absence of NSCLC, methods are also described herein for the grouping of multiple subsets of the NSCLC biomarkers that are each useful as a panel of three or more biomarkers. Thus, various embodiments of the instant application provide combinations comprising N biomarkers, wherein N is at least three biomarkers. In other embodiments, N is selected to be any number from 2-59 biomarkers. It will be appreciated that N can be selected to be any number from any of the above described ranges, as well as similar, but higher order, ranges. In accordance with any of the methods described herein, biomarker values can be detected and classified individually or they can be detected and classified collectively, as for example in a multiplex assay format.

Classification of Biomarkers and Calculation of Disease Scores

A biomarker “signature” for a given diagnostic test contains a set of markers, each marker having different levels in the populations of interest. Different levels, in this context, may refer to different means of the marker levels for the individuals in two or more groups, or different variances in the two or more groups, or a combination of both. For the simplest form of a diagnostic test, these markers can be used to assign an unknown sample from an individual into one of two groups, either diseased or not diseased. The assignment of a sample into one of two or more groups is known as classification, and the procedure used to accomplish this assignment is known as a classifier or a classification method. Classification methods may also be referred to as scoring methods. There are many classification methods that can be used to construct a diagnostic classifier from a set of biomarker values. In general, classification methods are most easily performed using supervised learning techniques where a data set is collected using samples obtained from individuals within two (or more, for multiple classification states) distinct groups one wishes to distinguish. Since the class (group or population) to which each sample belongs is known in advance for each sample, the classification method can be trained to give the desired classification response. It is also possible to use unsupervised learning techniques to produce a diagnostic classifier.

Common approaches for developing diagnostic classifiers include decision trees; bagging, boosting, forests and random forests; rule inference based learning; Parzen Windows; linear models; logistic; neural network methods; unsupervised clustering; K-means; hierarchical ascending/descending; semi-supervised learning; prototype methods; nearest neighbor; kernel density estimation; support vector machines; hidden Markov models; Boltzmann Learning; and classifiers may be combined either simply or in ways which minimize particular objective functions. For a review, see, e.g., Pattern Classification, R. O. Duda, et al., editors, John Wiley & Sons, 2nd edition, 2001; see also, The Elements of Statistical Learning—Data Mining, Inference, and Prediction, T. Hastie, et al., editors, Springer Science+Business Media, LLC, 2nd edition, 2009; each of which is incorporated by reference in its entirety.

To produce a classifier using supervised learning techniques, a set of samples called training data are obtained. In the context of diagnostic tests, training data includes samples from the distinct groups (classes) to which unknown samples will later be assigned. For example, samples collected from individuals in a control population and individuals in a particular disease population can constitute training data to develop a classifier that can classify unknown samples (or, more particularly, the individuals from whom the samples were obtained) as either having the disease or being free from the disease. The development of the classifier from the training data is known as training the classifier. Specific details on classifier training depend on the nature of the supervised learning technique. For purposes of illustration, an example of training a naïve Bayesian classifier will be described below (see, e.g., Pattern Classification, R. O. Duda, et al., editors, John Wiley & Sons, 2nd edition, 2001; see also, The Elements of Statistical Learning—Data Mining, Inference, and Prediction, T. Hastie, et al., editors, Springer Science+Business Media, LLC, 2nd edition, 2009).

Since typically there are many more potential biomarker values than samples in a training set, care must be used to avoid over-fitting. Over-fitting occurs when a statistical model describes random error or noise instead of the underlying relationship. Over-fitting can be avoided in a variety of way, including, for example, by limiting the number of markers used in developing the classifier, by assuming that the marker responses are independent of one another, by limiting the complexity of the underlying statistical model employed, and by ensuring that the underlying statistical model conforms to the data.

An illustrative example of the development of a diagnostic test using a set of biomarkers includes the application of a naïve Bayes classifier, a simple probabilistic classifier based on Bayes theorem with strict independent treatment of the biomarkers. Each biomarker is described by a class-dependent probability density function (pdf) for the measured RFU values or log RFU (relative fluorescence units) values in each class. The joint pdfs for the set of markers in one class is assumed to be the product of the individual class-dependent pdfs for each biomarker. Training a naïve Bayes classifier in this context amounts to assigning parameters (“parameterization”) to characterize the class dependent pdfs. Any underlying model for the class-dependent pdfs may be used, but the model should generally conform to the data observed in the training set.

Specifically, the class-dependent probability of measuring a value x_(i) for biomarker i in the disease class is written as p(x_(i)|d) and the overall naïve Bayes probability of observing n markers with values {tilde over (x)}=(x₁, x₂, . . . x_(n)) is written as p({tilde over (x)}|d)=Π_(i=1) ^(n)p(x_(i)|d) where the individual x_(i)s are the measured biomarker levels in RFU or log RFU. The classification assignment for an unknown is facilitated by calculating the probability of being diseased p(d|{tilde over (x)}) having measured {tilde over (x)} compared to the probability of being disease free (control) p(c|{tilde over (x)}) for the same measured values. The ratio of these probabilities is computed from the class-dependent pdfs by application of Bayes theorem, i.e.,

$\frac{p\left( {d\overset{\sim}{x}} \right)}{p\left( {c\overset{\sim}{x}} \right)} = \frac{{p\left( {\overset{\sim}{x}d} \right)}{p(d)}}{{p\left( {\overset{\sim}{x}c} \right)}\left( {1 - {p(d)}} \right)}$

where p(d) is the prevalence of the disease in the population appropriate to the test. Taking the logarithm of both sides of this ratio and substituting the naïve Bayes class-dependent probabilities from above gives

${\ln \left( \frac{p\left( {d\overset{\sim}{x}} \right)}{p\left( {c\overset{\sim}{x}} \right)} \right)} = {{\sum\limits_{i = 1}^{n}{\ln \left( \frac{p\left( {x_{i}d} \right)}{p\left( {x_{i}c} \right)} \right)}} + {{\ln \left( \frac{p(d)}{1 - {p(d)}} \right)}.}}$

This form is known as the log likelihood ratio and simply states that the log likelihood of being free of the particular disease versus having the disease and is primarily composed of the sum of individual log likelihood ratios of the n individual biomarkers. In its simplest form, an unknown sample (or, more particularly, the individual from whom the sample was obtained) is classified as being free of the disease if the above ratio is greater than zero and having the disease if the ratio is less than zero.

In one exemplary embodiment, the class-dependent biomarker pdfs p(x_(i)|c) and p(x_(i)|d) are assumed to be normal or log-normal distributions in the measured RFU values x_(i), i.e.

${{p\left( {x_{i}c} \right)} = {\frac{1}{\sqrt{2\pi}\sigma_{c,i}}{\exp\left( {- \frac{\left( {x_{i} - \mu_{c,i}} \right)^{2}}{2\sigma_{c,i}^{2}}} \right)}}},$

with a similar expression for p(x_(i)|d) with μ_(d) and σ_(d). Parameterization of the model requires estimation of two parameters for each class-dependent pdf, a mean μ and a variance σ², from the training data. This may be accomplished in a number of ways, including, for example, by maximum likelihood estimates, by least-squares, and by any other methods known to one skilled in the art. Substituting the normal distributions for μ and σ into the log-likelihood ratio defined above gives the following expression:

${\ln \left( \frac{p\left( {d\overset{\sim}{x}} \right)}{p\left( {c\overset{\sim}{x}} \right)} \right)} = {{\sum\limits_{i = 1}^{n}{\ln \left( \frac{\sigma_{c,i}}{\sigma_{d,i}} \right)}} - {\frac{1}{2}{\sum\limits_{i = 1}^{n}\left\lbrack {\left( \frac{x_{i} - \mu_{d,i}}{\sigma_{d,i}} \right)^{2} - \left( \frac{x_{i} - \mu_{c,i}}{\sigma_{c,i}} \right)^{2}} \right\rbrack}} + {\ln \left( \frac{p(d)}{1 - {p(d)}} \right)}}$

Once a set of μs and σ²s have been defined for each pdf in each class from the training data and the disease prevalence in the population is specified, the Bayes classifier is fully determined and may be used to classify unknown samples with measured values {tilde over (x)}.

The performance of the naïve Bayes classifier is dependent upon the number and quality of the biomarkers used to construct and train the classifier. A single biomarker will perform in accordance with its KS-distance (Kolmogorov-Smirnov), as defined in Example 3, below. If a classifier performance metric is defined as the area under the receiver operator characteristic curve (AUC), a perfect classifier will have a score of 1 and a random classifier, on average, will have a score of 0.5. The definition of the KS-distance between two sets A and B of sizes n and m is the value, D_(n,m)=sup_(x)|F_(A,n)(x)−F_(B,m)(x)|, which is the largest difference between two empirical cumulative distribution functions (cdf). The empirical cdf for a set A of n observations X_(i) is defined as,

${{F_{A,n}(x)} = {\frac{1}{n}{\sum\limits_{i = 1}^{n}I_{X_{i} \leq x}}}},$

where I_(X) _(i) ≦x is the indicator function which is equal to 1 if X_(i)<x and is otherwise equal to 0. By definition, this value is bounded between 0 and 1, where a KS-distance of 1 indicates that the emperical distributions do not overlap.

The addition of subsequent markers with good KS distances (>0.3, for example) will, in general, improve the classification performance if the subsequently added markers are independent of the first marker. Using the area under the ROC curve (AUC) as a classifier score, it is straightforward to generate many high scoring classifiers with a variation of a greedy algorithm. (A greedy algorithm is any algorithm that follows the problem solving metaheuristic of making the locally optimal choice at each stage with the hope of finding the global optimum.)

The algorithm approach used here is described in detail in Example 4. Briefly, all single analyte classifiers are generated from a table of potential biomarkers and added to a list. Next, all possible additions of a second analyte to each of the stored single analyte classifiers is then performed, saving a predetermined number of the best scoring pairs, say, for example, a thousand, on a new list. All possible three marker classifiers are explored using this new list of the best two-marker classifiers, again saving the best thousand of these. This process continues until the score either plateaus or begins to deteriorate as additional markers are added. Those high scoring classifiers that remain after convergence can be evaluated for the desired performance for an intended use. For example, in one diagnostic application, classifiers with a high sensitivity and modest specificity may be more desirable than modest sensitivity and high specificity. In another diagnostic application, classifiers with a high specificity and a modest sensitivity may be more desirable. The desired level of performance is generally selected based upon a trade-off that must be made between the number of false positives and false negatives that can each be tolerated for the particular diagnostic application. Such trade-offs generally depend on the medical consequences of an error, either false positive or false negative.

Various other techniques are known in the art and may be employed to generate many potential classifiers from a list of biomarkers using a naïve Bayes classifier. In one embodiment, what is referred to as a genetic algorithm can be used to combine different markers using the fitness score as defined above. Genetic algorithms are particularly well suited to exploring a large diverse population of potential classifiers. In another embodiment, so-called ant colony optimization can be used to generate sets of classifiers. Other strategies that are known in the art can also be employed, including, for example, other evolutionary strategies as well as simulated annealing and other stochastic search methods. Metaheuristic methods, such as, for example, harmony search may also be employed.

Exemplary embodiments use any number of the NSCLC biomarkers listed in Table 1 in various combinations to produce diagnostic tests for detecting NSCLC (see Example 2 for a detailed description of how these biomarkers were identified). In one embodiment, a method for diagnosing NSCLC uses a naïve Bayes classification method in conjunction with any number of the NSCLC biomarkers listed in Table 1. In an illustrative example (Example 3), the simplest test for detecting NSCLC from a population of smokers and benign pulmonary nodules can be constructed using a single biomarker, for example, MMP7 which is differentially expressed in NSCLC with a KS-distance of 0.59. Using the parameters, μ_(c,i), σ_(c,i), and, σ_(d,i) for MMP7 from Table 16 and the equation for the log-likelihood described above, a diagnostic test with an AUC of 0.803 can be derived, see Table 15. The ROC curve for this test is displayed in FIG. 2.

Addition of biomarker CLIC1, for example, with a KS-distance of 0.53, significantly improves the classifier performance to an AUC of 0.883. Note that the score for a classifier constructed of two biomarkers is not a simple sum of the KS-distances; KS-distances are not additive when combining biomarkers and it takes many more weak markers to achieve the same level of performance as a strong marker. Adding a third marker, STX1A, for example, boosts the classifier performance to an AUC of 0.901. Adding additional biomarkers, such as, for example, CHRDL1, PA2G4, SERPINA1, BDNF, GHR, TGFBI, and NME2, produces a series of NSCLC tests summarized in Table 15 and displayed as a series of ROC curves in FIG. 3. The score of the classifiers as a function of the number of analytes used in classifier construction is displayed in FIG. 4. The AUC of this exemplary ten-marker classifier is 0.948.

The markers listed in Table 1 can be combined in many ways to produce classifiers for diagnosing NSCLC. In some embodiments, panels of biomarkers are comprised of different numbers of analytes depending on a specific diagnostic performance criterion that is selected. For example, certain combinations of biomarkers will produce tests that are more sensitive (or more specific) than other combinations.

Once a panel is defined to include a particular set of biomarkers from Table 1 and a classifier is constructed from a set of training data, the definition of the diagnostic test is complete. In one embodiment, the procedure used to classify an unknown sample is outlined in FIG. 1A. In another embodiment the procedure used to classify an unknown sample is outlined in FIG. 1B. The biological sample is appropriately diluted and then run in one or more assays to produce the relevant quantitative biomarker levels used for classification. The measured biomarker levels are used as input for the classification method that outputs a classification and an optional score for the sample that reflects the confidence of the class assignment.

Table 1 identifies 59 biomarkers that are useful for diagnosing NSCLC. This is a surprisingly larger number than expected when compared to what is typically found during biomarker discovery efforts and may be attributable to the scale of the described study, which encompassed over 1000 proteins measured in hundreds of individual samples, in some cases at concentrations in the low femtomolar range. Presumably, the large number of discovered biomarkers reflects the diverse biochemical pathways implicated in both tumor biology and the body's response to the tumor's presence; each pathway and process involves many proteins. The results show that no single protein of a small group of proteins is uniquely informative about such complex processes; rather, that multiple proteins are involved in relevant processes, such as apoptosis or extracellular matrix repair, for example.

Given the numerous biomarkers identified during the described study, one would expect to be able to derive large numbers of high-performing classifiers that can be used in various diagnostic methods. To test this notion, tens of thousands of classifiers were evaluated using the biomarkers in Table 1. As described in Example 4, many subsets of the biomarkers presented in Table 1 can be combined to generate useful classifiers. By way of example, descriptions are provided for classifiers containing 1, 2, and 3 biomarkers for detection of NSCLC. As described in Example 4, all classifiers that were built using the biomarkers in Table 1 perform distinctly better than classifiers that were built using “non-markers”.

The performance of classifiers obtained by randomly excluding some of the markers in Table 1, which resulted in smaller subsets from which to build the classifiers, was also tested. As described in Example 4, the classifiers that were built from random subsets of the markers in Table 1 performed similarly to optimal classifiers that were built using the full list of markers in Table 1.

The performance of ten-marker classifiers obtained by excluding the “best” individual markers from the ten-marker aggregation was also tested. As described in Example 4, classifiers constructed without the “best” markers in Table 1 also performed well. Many subsets of the biomarkers listed in Table 1 performed close to optimally, even after removing the top 15 of the markers listed in the Table. This implies that the performance characteristics of any particular classifier are likely not due to some small core group of biomarkers and that the disease process likely impacts numerous biochemical pathways, which alters the expression level of many proteins.

The results from Example 4 suggest certain possible conclusions: First, the identification of a large number of biomarkers enables their aggregation into a vast number of classifiers that offer similarly high performance. Second, classifiers can be constructed such that particular biomarkers may be substituted for other biomarkers in a manner that reflects the redundancies that undoubtedly pervade the complexities of the underlying disease processes. That is to say, the information about the disease contributed by any individual biomarker identified in Table 1 overlaps with the information contributed by other biomarkers, such that it may be that no particular biomarker or small group of biomarkers in Table 1 must be included in any classifier.

Exemplary embodiments use naïve Bayes classifiers constructed from the data in Table 16 to classify an unknown sample. The procedure is outlined in FIGS. 1A and 1B. In one embodiment, the biological sample is optionally diluted and run in a multiplexed aptamer assay. The data from the assay are normalized and calibrated as outlined in Example 3, and the resulting biomarker levels are used as input to a Bayes classification scheme. The loglikelihood ratio is computed for each measured biomarker individually and then summed to produce a final classification score, which is also referred to as a diagnostic score. The resulting assignment as well as the overall classification score can be reported. Optionally, the individual log-likelihood risk factors computed for each biomarker level can be reported as well. The details of the classification score calculation are presented in Example 3.

Kits

Any combination of the biomarkers of Table 1 (as well as additional biomedical information) can be detected using a suitable kit, such as for use in performing the methods disclosed herein. Furthermore, any kit can contain one or more detectable labels as described herein, such as a fluorescent moiety, etc.

In one embodiment, a kit includes (a) one or more capture reagents (such as, for example, at least one aptamer or antibody) for detecting one or more biomarkers in a biological sample, wherein the biomarkers include any of the biomarkers set forth in Table 1, and optionally (b) one or more software or computer program products for classifying the individual from whom the biological sample was obtained as either having or not having NSCLC or for determining the likelihood that the individual has NSCLC, as further described herein. Alternatively, rather than one or more computer program products, one or more instructions for manually performing the above steps by a human can be provided.

The combination of a solid support with a corresponding capture reagent and a signal generating material is referred to herein as a “detection device” or “kit”. The kit can also include instructions for using the devices and reagents, handling the sample, and analyzing the data. Further the kit may be used with a computer system or software to analyze and report the result of the analysis of the biological sample.

The kits can also contain one or more reagents (e.g., solubilization buffers, detergents, washes, or buffers) for processing a biological sample. Any of the kits described herein can also include, e.g., buffers, blocking agents, mass spectrometry matrix materials, antibody capture agents, positive control samples, negative control samples, software and information such as protocols, guidance and reference data.

In one aspect, the invention provides kits for the analysis of NSCLC status. The kits include PCR primers for one or more biomarkers selected from Table 1. The kit may further include instructions for use and correlation of the biomarkers with NSCLC. The kit may also include a DNA array containing the complement of one or more of the biomarkers selected from Table 1, reagents, and/or enzymes for amplifying or isolating sample DNA. The kits may include reagents for real-time PCR, for example, TaqMan probes and/or primers, and enzymes.

For example, a kit can comprise (a) reagents comprising at least capture reagent for quantifying one or more biomarkers in a test sample, wherein said biomarkers comprise the biomarkers set forth in Table 1, or any other biomarkers or biomarkers panels described herein, and optionally (b) one or more algorithms or computer programs for performing the steps of comparing the amount of each biomarker quantified in the test sample to one or more predetermined cutoffs and assigning a score for each biomarker quantified based on said comparison, combining the assigned scores for each biomarker quantified to obtain a total score, comparing the total score with a predetermined score, and using said comparison to determine whether an individual has NSCLC. Alternatively, rather than one or more algorithms or computer programs, one or more instructions for manually performing the above steps by a human can be provided.

Computer Methods and Software

Once a biomarker or biomarker panel is selected, a method for diagnosing an individual can comprise the following: 1) collect or otherwise obtain a biological sample; 2) perform an analytical method to detect and measure the biomarker or biomarkers in the panel in the biological sample; 3) perform any data normalization or standardization required for the method used to collect biomarker values; 4) calculate the marker score; 5) combine the marker scores to obtain a total diagnostic score; and 6) report the individual's diagnostic score. In this approach, the diagnostic score may be a single number determined from the sum of all the marker calculations that is compared to a preset threshold value that is an indication of the presence or absence of disease. Or the diagnostic score may be a series of bars that each represent a biomarker value and the pattern of the responses may be compared to a pre-set pattern for determination of the presence or absence of disease.

At least some embodiments of the methods described herein can be implemented with the use of a computer. An example of a computer system 100 is shown in FIG. 6. With reference to FIG. 6, system 100 is shown comprised of hardware elements that are electrically coupled via bus 108, including a processor 101, input device 102, output device 103, storage device 104, computer-readable storage media reader 105 a, communications system 106 processing acceleration (e.g., DSP or special-purpose processors) 107 and memory 109. Computer-readable storage media reader 105 a is further coupled to computer-readable storage media 105 b, the combination comprehensively representing remote, local, fixed and/or removable storage devices plus storage media, memory, etc. for temporarily and/or more permanently containing computer-readable information, which can include storage device 104, memory 109 and/or any other such accessible system 100 resource. System 100 also comprises software elements (shown as being currently located within working memory 191) including an operating system 192 and other code 193, such as programs, data and the like.

With respect to FIG. 6, system 100 has extensive flexibility and configurability. Thus, for example, a single architecture might be utilized to implement one or more servers that can be further configured in accordance with currently desirable protocols, protocol variations, extensions, etc. However, it will be apparent to those skilled in the art that embodiments may well be utilized in accordance with more specific application requirements. For example, one or more system elements might be implemented as sub-elements within a system 100 component (e.g., within communications system 106). Customized hardware might also be utilized and/or particular elements might be implemented in hardware, software or both. Further, while connection to other computing devices such as network input/output devices (not shown) may be employed, it is to be understood that wired, wireless, modem, and/or other connection or connections to other computing devices might also be utilized.

In one aspect, the system can comprise a database containing features of biomarkers characteristic of NSCLC. The biomarker data (or biomarker information) can be utilized as an input to the computer for use as part of a computer implemented method. The biomarker data can include the data as described herein.

In one aspect, the system further comprises one or more devices for providing input data to the one or more processors.

The system further comprises a memory for storing a data set of ranked data elements.

In another aspect, the device for providing input data comprises a detector for detecting the characteristic of the data element, e.g., such as a mass spectrometer or gene chip reader.

The system additionally may comprise a database management system. User requests or queries can be formatted in an appropriate language understood by the database management system that processes the query to extract the relevant information from the database of training sets.

The system may be connectable to a network to which a network server and one or more clients are connected. The network may be a local area network (LAN) or a wide area network (WAN), as is known in the art. Preferably, the server includes the hardware necessary for running computer program products (e.g., software) to access database data for processing user requests.

The system may include an operating system (e.g., UNIX or Linux) for executing instructions from a database management system. In one aspect, the operating system can operate on a global communications network, such as the Internet, and utilize a global communications network server to connect to such a network.

The system may include one or more devices that comprise a graphical display interface comprising interface elements such as buttons, pull down menus, scroll bars, fields for entering text, and the like as are routinely found in graphical user interfaces known in the art. Requests entered on a user interface can be transmitted to an application program in the system for formatting to search for relevant information in one or more of the system databases. Requests or queries entered by a user may be constructed in any suitable database language.

The graphical user interface may be generated by a graphical user interface code as part of the operating system and can be used to input data and/or to display inputted data. The result of processed data can be displayed in the interface, printed on a printer in communication with the system, saved in a memory device, and/or transmitted over the network or can be provided in the form of the computer readable medium.

The system can be in communication with an input device for providing data regarding data elements to the system (e.g., expression values). In one aspect, the input device can include a gene expression profiling system including, e.g., a mass spectrometer, gene chip or array reader, and the like.

The methods and apparatus for analyzing NSCLC biomarker information according to various embodiments may be implemented in any suitable manner, for example, using a computer program operating on a computer system. A conventional computer system comprising a processor and a random access memory, such as a remotely-accessible application server, network server, personal computer or workstation may be used. Additional computer system components may include memory devices or information storage systems, such as a mass storage system and a user interface, for example a conventional monitor, keyboard and tracking device. The computer system may be a stand-alone system or part of a network of computers including a server and one or more databases.

The NSCLC biomarker analysis system can provide functions and operations to complete data analysis, such as data gathering, processing, analysis, reporting and/or diagnosis. For example, in one embodiment, the computer system can execute the computer program that may receive, store, search, analyze, and report information relating to the NSCLC biomarkers. The computer program may comprise multiple modules performing various functions or operations, such as a processing module for processing raw data and generating supplemental data and an analysis module for analyzing raw data and supplemental data to generate a NSCLC status and/or diagnosis. Diagnosing NSCLC status may comprise generating or collecting any other information, including additional biomedical information, regarding the condition of the individual relative to the disease, identifying whether further tests may be desirable, or otherwise evaluating the health status of the individual.

Referring now to FIG. 7, an example of a method of utilizing a computer in accordance with principles of a disclosed embodiment can be seen. In FIG. 7, a flowchart 3000 is shown. In block 3004, biomarker information can be retrieved for an individual. The biomarker information can be retrieved from a computer database, for example, after testing of the individual's biological sample is performed. The biomarker information can comprise biomarker values that each correspond to one of at least N biomarkers selected from a group consisting of the biomarkers provided in Table 1, wherein N=2-59. In block 3008, a computer can be utilized to classify each of the biomarker values. And, in block 3012, a determination can be made as to the likelihood that an individual has NSCLC based upon a plurality of classifications. The indication can be output to a display or other indicating device so that it is viewable by a person. Thus, for example, it can be displayed on a display screen of a computer or other output device.

Referring now to FIG. 8, an alternative method of utilizing a computer in accordance with another embodiment can be illustrated via flowchart 3200. In block 3204, a computer can be utilized to retrieve biomarker information for an individual. The biomarker information comprises a biomarker value corresponding to a biomarker selected from the group of biomarkers provided in Table 1. In block 3208, a classification of the biomarker value can be performed with the computer. And, in block 3212, an indication can be made as to the likelihood that the individual has NSCLC based upon the classification. The indication can be output to a display or other indicating device so that it is viewable by a person. Thus, for example, it can be displayed on a display screen of a computer or other output device.

Some embodiments described herein can be implemented so as to include a computer program product. A computer program product may include a computer readable medium having computer readable program code embodied in the medium for causing an application program to execute on a computer with a database.

As used herein, a “computer program product” refers to an organized set of instructions in the form of natural or programming language statements that are contained on a physical media of any nature (e.g., written, electronic, magnetic, optical or otherwise) and that may be used with a computer or other automated data processing system. Such programming language statements, when executed by a computer or data processing system, cause the computer or data processing system to act in accordance with the particular content of the statements. Computer program products include without limitation: programs in source and object code and/or test or data libraries embedded in a computer readable medium. Furthermore, the computer program product that enables a computer system or data processing equipment device to act in pre-selected ways may be provided in a number of forms, including, but not limited to, original source code, assembly code, object code, machine language, encrypted or compressed versions of the foregoing and any and all equivalents.

In one aspect, a computer program product is provided for indicating a likelihood of NSCLC. The computer program product includes a computer readable medium embodying program code executable by a processor of a computing device or system, the program code comprising: code that retrieves data attributed to a biological sample from an individual, wherein the data comprises biomarker values that each correspond to one of at least N biomarkers in the biological sample selected from the group of biomarkers provided in Table 1, wherein N=2-59; and code that executes a classification method that indicates a NSCLC status of the individual as a function of the biomarker values.

In still another aspect, a computer program product is provided for indicating a likelihood of NSCLC. The computer program product includes a computer readable medium embodying program code executable by a processor of a computing device or system, the program code comprising: code that retrieves data attributed to a biological sample from an individual, wherein the data comprises a biomarker value corresponding to a biomarker in the biological sample selected from the group of biomarkers provided in Table 1; and code that executes a classification method that indicates a NSCLC status of the individual as a function of the biomarker value.

While various embodiments have been described as methods or apparatuses, it should be understood that embodiments can be implemented through code coupled with a computer, e.g., code resident on a computer or accessible by the computer. For example, software and databases could be utilized to implement many of the methods discussed above. Thus, in addition to embodiments accomplished by hardware, it is also noted that these embodiments can be accomplished through the use of an article of manufacture comprised of a computer usable medium having a computer readable program code embodied therein, which causes the enablement of the functions disclosed in this description. Therefore, it is desired that embodiments also be considered protected by this patent in their program code means as well. Furthermore, the embodiments may be embodied as code stored in a computer-readable memory of virtually any kind including, without limitation, RAM, ROM, magnetic media, optical media, or magneto-optical media. Even more generally, the embodiments could be implemented in software, or in hardware, or any combination thereof including, but not limited to, software running on a general purpose processor, microcode, PLAs, or ASICs.

It is also envisioned that embodiments could be accomplished as computer signals embodied in a carrier wave, as well as signals (e.g., electrical and optical) propagated through a transmission medium. Thus, the various types of information discussed above could be formatted in a structure, such as a data structure, and transmitted as an electrical signal through a transmission medium or stored on a computer readable medium.

It is also noted that many of the structures, materials, and acts recited herein can be recited as means for performing a function or step for performing a function. Therefore, it should be understood that such language is entitled to cover all such structures, materials, or acts disclosed within this specification and their equivalents, including the matter incorporated by reference.

The biomarker identification process, the utilization of the biomarkers disclosed herein, and the various methods for determining biomarker values are described in detail above with respect to NSCLC. However, the application of the process, the use of identified biomarkers, and the methods for determining biomarker values are fully applicable to other specific types of cancer, to cancer generally, to any other disease or medical condition, or to the identification of individuals who may or may not be benefited by an ancillary medical treatment. Except when referring to specific results related to NSCLC, as is clear from the context, references herein to NSCLC may be understood to include other types of cancer, cancer generally, or any other disease or medical condition.

EXAMPLES

The following examples are provided for illustrative purposes only and are not intended to limit the scope of the application as defined by the appended claims. All examples described herein were carried out using standard techniques, which are well known and routine to those of skill in the art. Routine molecular biology techniques described in the following examples can be carried out as described in standard laboratory manuals, such as Sambrook et al., Molecular Cloning: A Laboratory Manual, 3rd. ed., Cold Spring Harbor Laboratory Press, Cold Spring Harbor, N.Y., (2001).

Example 1 Multiplexed Aptamer Analysis of Samples

This example describes the multiplex aptamer assay used to analyze the samples and controls for the identification of the biomarkers set forth in Table 1 (see FIG. 9) and the identification of the cancer biomarkers set forth in Table 19. For the NSCLC, mesothelioma, and renal cell carcinoma studies, the multiplexed analysis utilized 1,034 aptamers, each unique to a specific target.

In this method, pipette tips were changed for each solution addition.

Also, unless otherwise indicated, most solution transfers and wash additions used the 96-well head of a Beckman Biomek FxP. Method steps manually pipetted used a twelve channel P200 Pipetteman (Rainin Instruments, LLC, Oakland, Calif.), unless otherwise indicated. A custom buffer referred to as SB17 was prepared in-house, comprising 40 mM HEPES, 100 mM NaCl, 5 mM KCl, 5 mM MgCl₂, 1 mM EDTA at pH 7.5. A custom buffer referred to as SB18 was prepared in-house, comprising 40 mM HEPES, 100 mM NaCl, 5 mM KCl, 5 mM MgCl₂ at pH 7.5. All steps were performed at room temperature unless otherwise indicated.

1. Preparation of Aptamer Stock Solution

Custom stock aptamer solutions for 5%, 0.316% and 0.01% serum were prepared at 2× concentration in 1×SB17, 0.05% Tween-20.

These solutions are stored at −20° C. until use. The day of the assay, each aptamer mix was thawed at 37° C. for 10 minutes, placed in a boiling water bath for 10 minutes and allowed to cool to 25° C. for 20 minutes with vigorous mixing in between each heating step. After heat-cool, 55 μL of each 2× aptamer mix was manually pipetted into a 96-well Hybaid plate and the plate foil sealed. The final result was three, 96-well, foil-sealed Hybaid plates with 5%, 0.316% or 0.01% aptamer mixes. The individual aptamer concentration was 2× final or 1 nM.

2. Assay Sample Preparation

Frozen aliquots of 100% serum or plasma, stored at −80° C., were placed in 25° C. water bath for 10 minutes. Thawed samples were placed on ice, gently vortexed (set on 4) for 8 seconds and then replaced on ice.

A 10% sample solution (2× final) was prepared by transferring 8 μL of sample using a 50 μL 8-channel spanning pipettor into 96-well Hybaid plates, each well containing 72 μL of the appropriate sample diluent at 4° C. (1×SB17 for serum or 0.8×SB18 for plasma, plus 0.06% Tween-20, 11.1 μM Z-block_(—)2, 0.44 mM MgCl₂, 2.2 mM AEBSF, 1.1 mM EGTA, 55.6 μM EDTA). This plate was stored on ice until the next sample dilution steps were initiated on the BiomekFxP robot.

To commence sample and aptamer equilibration, the 10% sample plate was briefly centrifuged and placed on the Beckman FX where it was mixed by pipetting up and down with the 96-well pipettor. A 0.632% sample plate (2× final) was then prepared by diluting 6 μL of the 10% sample into 89 μL of 1×SB17, 0.05% Tween-20 with 2 mM AEBSF. Next, dilution of 6 μL of the resultant 0.632% sample into 184 μL of 1×SB17, 0.05% Tween-20 made a 0.02% sample plate (2× final). Dilutions were done on the Beckman Biomek FxP. After each transfer, the solutions were mixed by pipetting up and down. The 3 sample dilution plates were then transferred to their respective aptamer solutions by adding 55 μL of the sample to 55 μL of the appropriate 2× aptamer mix. The sample and aptamer solutions were mixed on the robot by pipetting up and down.

3. Sample Equilibration Binding

The sample/aptamer plates were foil sealed and placed into a 37° C. incubator for 3.5 hours before proceeding to the Catch 1 step.

4. Preparation of Catch 2 Bead Plate

An 11 mL aliquot of MyOne (Invitrogen Corp., Carlsbad, Calif.) Streptavidin C1 beads (10 mg/mL) was washed 2 times with equal volumes of 20 mM NaOH (5 minute incubation for each wash), 3 times with equal volumes of 1×SB17, 0.05% Tween-20 and resuspended in 11 mL 1×SB17, 0.05% Tween-20. Using a 12-span multichannel pipettor, 50 μL of this solution was manually pipetted into each well of a 96-well Hybaid plate. The plate was then covered with foil and stored at 4° C. for use in the assay.

5. Preparation of Catch 1 Bead Plates

Three 0.45 μm Millipore HV plates (Durapore membrane, Cat# MAHVN4550) were equilibrated with 100 μL of 1×SB17, 0.05% Tween-20 for at least 10 minutes. The equilibration buffer was then filtered through the plate and 133.3 μL of a 7.5% streptavidin-agarose bead slurry (in 1×SB17, 0.05% Tween-20) was added into each well. To keep the streptavidin-agarose beads suspended while transferring them into the filter plate, the bead solution was manually mixed with a 200 μL, 12-channel pipettor, at least 6 times between pipetting events. After the beads were distributed across the 3 filter plates, a vacuum was applied to remove the bead supernatant. Finally, the beads were washed in the filter plates with 200 μL 1×SB17, 0.05% Tween-20 and then resuspended in 200 μL 1×SB17, 0.05% Tween-20. The bottoms of the filter plates were blotted and the plates stored for use in the assay.

6. Loading the Cytomat

The cytomat was loaded with all tips, plates, all reagents in troughs (except NHS-biotin reagent which was prepared fresh right before addition to the plates), 3 prepared Catch 1 filter plates and 1 prepared MyOne plate.

7. Catch 1

After a 3.5 hour equilibration time, the sample/aptamer plates were removed from the incubator, centrifuged for about 1 minute, cover removed, and placed on the deck of the Beckman Biomek FxP. The Beckman Biomek FxP program was initiated. All subsequent steps in Catch 1 were performed by the Beckman Biomek FxP robot unless otherwise noted. Within the program, the vacuum was applied to the Catch 1 filter plates to remove the bead supernatant. One hundred microlitres of each of the 5%, 0.316% and 0.01% equilibration binding reactions were added to their respective Catch 1 filtration plates, and each plate was mixed using an on-deck orbital shaker at 800 rpm for 10 minutes.

Unbound solution was removed via vacuum filtration. The Catch 1 beads were washed with 190 μL of 100 μM biotin in 1×SB17, 0.05% Tween-20 followed by 5×190 μL of 1×SB17, 0.05% Tween-20 by dispensing the solution and immediately drawing a vacuum to filter the solution through the plate.

8. Tagging

A 100 mM NHS-PEO4-biotin aliquot in anhydrous DMSO was thawed at 37° C. for 6 minutes and then diluted 1:100 with tagging buffer (SB17 at pH 7.25, 0.05% Tween-20). Upon a robot prompt, the diluted NHS-PEO4-biotin reagent was manually added to an on-deck trough and the robot program was manually re-initiated to dispense 100 μL of the NHS-PEO4-biotin into each well of each Catch 1 filter plate. This solution was allowed to incubate with Catch 1 beads shaking at 800 rpm for 5 minutes on the orbital shakers.

9. Kinetic Challenge and Photo-Cleavage

The tagging reaction was removed by vacuum filtration and quenched by the addition of 150 μL of 20 mM glycine in 1×SB17, 0.05% Tween-20 to the Catch 1 plates. The NHS-tag/glycine solution was removed via vacuum filtration. Next, 1500 μL 20 mM glycine (1×SB17, 0.05% Tween-20) was added to each plate and incubated for 1 minute on orbital shakers at 800 rpm before removal by vacuum filtration.

The wells of the Catch 1 plates were subsequently washed three times by adding 190 μL 1×SB17, 0.05% Tween-20, followed by vacuum filtration and then by adding 190 1μL 1×SB17, 0.05% Tween-20 with shaking for 1 minute at 800 rpm followed by vacuum filtration. After the last wash the plates were placed on top of a 1 mL deep-well plate and removed from the deck. The Catch 1 plates were centrifuged at 1000 rpm for 1 minute to remove as much extraneous volume from the agarose beads before elution as possible.

The plates were placed back onto the Beckman Biomek FxP and 85 μL of 10 mM DxSO4 in 1×SB17, 0.05% Tween-20 was added to each well of the filter plates.

The filter plates were removed from the deck, placed onto a Variomag Thermoshaker (Thermo Fisher Scientific, Inc., Waltham, Mass.) under the BlackRay (Ted Pella, Inc., Redding, Calif.) light sources, and irradiated for 5 minutes while shaking at 800 rpm. After the 5 minute incubation the plates were rotated 180 degrees and irradiated with shaking for 5 minutes more.

The photocleaved solutions were sequentially eluted from each Catch 1 plate into a common deep well plate by first placing the 5% Catch 1 filter plate on top of a 1 mL deep-well plate and centrifuging at 1000 rpm for 1 minute. The 0.316% and 0.01% Catch 1 plates were then sequentially centrifuged into the same deep well plate.

10. Catch 2 Bead Capture

The 1 mL deep well block containing the combined eluates of Catch 1 was placed on the deck of the Beckman Biomek FxP for Catch 2.

The robot transferred all of the photo-cleaved eluate from the 1 mL deep-well plate onto the Hybaid plate containing the previously prepared Catch 2 MyOne magnetic beads (after removal of the MyOne buffer via magnetic separation).

The solution was incubated while shaking at 1350 rpm for 5 minutes at 25° C. on a Variomag Thermoshaker (Thermo Fisher Scientific, Inc., Waltham, Mass.).

The robot transferred the plate to the on deck magnetic separator station. The plate was incubated on the magnet for 90 seconds before removal and discarding of the supernatant.

11. 37° C. 30% Glycerol Washes

The Catch 2 plate was moved to the on-deck thermal shaker and 75 μL of 1×SB17, 0.05% Tween-20 was transferred to each well. The plate was mixed for 1 minute at 1350 rpm and 37° C. to resuspend and warm the beads. To each well of the Catch 2 plate, 75 μL of 60% glycerol at 37° C. was transferred and the plate continued to mix for another minute at 1350 rpm and 37° C. The robot transferred the plate to the 37° C. magnetic separator where it was incubated on the magnet for 2 minutes and then the robot removed and discarded the supernatant. These washes were repeated two more times.

After removal of the third 30% glycerol wash from the Catch 2 beads, 150 μL of 1×SB17, 0.05% Tween-20 was added to each well and incubated at 37° C., shaking at 1350 rpm for 1 minute, before removal by magnetic separation on the 37° C. magnet.

The Catch 2 beads were washed a final time using 150 μL 1×SB17, 0.05% Tween-20 with incubation for 1 minute while shaking at 1350 rpm at 25° C. prior to magnetic separation.

12. Catch 2 Bead Elution and Neutralization

The aptamers were eluted from Catch 2 beads by adding 105 μL of 100 mM CAPSO with 1M NaCl, 0.05% Tween-20 to each well. The beads were incubated with this solution with shaking at 1300 rpm for 5 minutes.

The Catch 2 plate was then placed onto the magnetic separator for 90 seconds prior to transferring 63 μL of the eluate to a new 96-well plate containing 7 μL of 500 mM HCl, 500 mM HEPES, 0.05% Tween-20 in each well. After transfer, the solution was mixed robotically by pipetting 60 μL up and down five times.

13. Hybridization

The Beckman Biomek FxP transferred 20 μL of the neutralized Catch 2 eluate to a fresh Hybaid plate, and 6 μL of 10× Agilent Block, containing a 10× spike of hybridization controls, was added to each well. Next, 30 μL of 2× Agilent Hybridization buffer was manually pipetted to the each well of the plate containing the neutralized samples and blocking buffer and the solution was mixed by manually pipetting 25 μL up and down 15 times slowly to avoid extensive bubble formation. The plate was spun at 1000 rpm for 1 minute.

Custom Agilent microarray slides (Agilent Technologies, Inc., Santa Clara, Calif.) were designed to contain probes complementary to the aptamer random region plus some primer region. For the majority of the aptamers, the optimal length of the complementary sequence was empirically determined and ranged between 40-50 nucleotides. For later aptamers a 46-mer complementary region was chosen by default. The probes were linked to the slide surface with a poly-T linker for a total probe length of 60 nucleotides.

A gasket slide was placed into an Agilent hybridization chamber and 40 μL of each of the samples containing hybridization and blocking solution was manually pipetted into each gasket. An 8-channel variable spanning pipettor was used in a manner intended to minimize bubble formation. Custom Agilent microarray slides (Agilent Technologies, Inc., Santa Clara, Calif.),with their Number Barcode facing up, were then slowly lowered onto the gasket slides (see Agilent manual for detailed description).

The top of the hybridization chambers were placed onto the slide/backing sandwich and clamping brackets slid over the whole assembly. These assemblies were tightly clamped by turning the screws securely.

Each slide/backing slide sandwich was visually inspected to assure the solution bubble could move freely within the sample. If the bubble did not move freely the hybridization chamber assembly was gently tapped to disengage bubbles lodged near the gasket.

The assembled hybridization chambers were incubated in an Agilent hybridization oven for 19 hours at 60° C. rotating at 20 rpm.

14. Post Hybridization Washing

Approximately 400 mL Agilent Wash Buffer 1 was placed into each of two separate glass staining dishes. One of the staining dishes was placed on a magnetic stir plate and a slide rack and stir bar were placed into the buffer.

A staining dish for Agilent Wash 2 was prepared by placing a stir bar into an empty glass staining dish.

A fourth glass staining dish was set aside for the final acetonitrile wash.

Each of six hybridization chambers was disassembled. One-by-one, the slide/backing sandwich was removed from its hybridization chamber and submerged into the staining dish containing Wash 1. The slide/backing sandwich was pried apart using a pair of tweezers, while still submerging the microarray slide. The slide was quickly transferred into the slide rack in the Wash 1 staining dish on the magnetic stir plate.

The slide rack was gently raised and lowered 5 times. The magnetic stirrer was turned on at a low setting and the slides incubated for 5 minutes.

When one minute was remaining for Wash 1, Wash Buffer 2 pre-warmed to 37° C. in an incubator was added to the second prepared staining dish. The slide rack was quickly transferred to Wash Buffer 2 and any excess buffer on the bottom of the rack was removed by scraping it on the top of the stain dish. The slide rack was gently raised and lowered 5 times. The magnetic stirrer was turned on at a low setting and the slides incubated for 5 minutes.

The slide rack was slowly pulled out of Wash 2, taking approximately 15 seconds to remove the slides from the solution.

With one minute remaining in Wash 2 acetonitrile (ACN) was added to the fourth staining dish. The slide rack was transferred to the acetonitrile stain dish. The slide rack was gently raised and lowered 5 times. The magnetic stirrer was turned on at a low setting and the slides incubated for 5 minutes.

The slide rack was slowly pulled out of the ACN stain dish and placed on an absorbent towel. The bottom edges of the slides were quickly dried and the slide was placed into a clean slide box.

15. Microarray Imaging

The microarray slides were placed into Agilent scanner slide holders and loaded into the Agilent Microarray scanner according to the manufacturers instructions.

The slides were imaged in the Cy3-channel at 5 μm resolution at the 100% PMT setting and the XRD option enabled at 0.05. The resulting tiff images were processed using Agilent feature extraction software version 10.5.

Example 2 Biomarker Identification

The identification of potential NSCLC biomarkers was performed for diagnosis of NSCLC in individuals with indeterminate pulmonary nodules identified with a CT scan or other imaging method, screening of high risk smokers for NSCLC, and diagnosing an individual with NSCLC. Enrollment criteria for this study were smokers, age 18 or older, able to give informed consent, and blood sample and documented diagnosis of NSCLC or benign findings. For cases, blood samples collected prior to treatment or surgery and subsequently diagnosed with NSCLC. Exclusion criteria included prior diagnosis or treatment of cancer (excluding squamous cell carcinoma of the skin) within 5 years of the blood draw. Serum samples were collected from 3 different sites and included 46 NSCLC samples and 218 control group samples as described in Table 17. The multiplexed aptamer affinity assay as described in Example 1 was used to measure and report the RFU value for 1,034 analytes in each of these 264 samples.

Each of the case and control populations were separately compared by generating class-dependent cumulative distribution functions (cdfs) for each of the 1,034 analytes. The KS-distance (Kolmogorov-Smirnov statistic) between values from two sets of samples is a non parametric measurement of the extent to which the empirical distribution of the values from one set (Set A) differs from the distribution of values from the other set (Set B). For any value of a threshold T some proportion of the values from Set A will be less than T, and some proportion of the values from Set B will be less than T. The KS-distance measures the maximum (unsigned) difference between the proportion of the values from the two sets for any choice of T.

This set of potential biomarkers can be used to build classifiers that assign samples to either a control or disease group. In fact, many such classifiers were produced from these sets of biomarkers and the frequency with which any biomarker was used in good scoring classifiers determined. Those biomarkers that occurred most frequently among the top scoring classifiers were the most useful for creating a diagnostic test. In this example, Bayesian classifiers were used to explore the classification space but many other supervised learning techniques may be employed for this purpose. The scoring fitness of any individual classifier was gauged by the area under the receiver operating characteristic curve (AUC of the ROC) of the classifier at the Bayesian surface assuming a disease prevalence of 0.5. This scoring metric varies from zero to one, with one being an error-free classifier. The details of constructing a Bayesian classifier from biomarker population measurements are described in Example 3.

Using the 59 analytes in Table 1, a total of 964 10-analyte classifiers were found with an AUC of 0.94 for diagnosing NSCLC from the control group. From this set of classifiers, a total of 12 biomarkers were found to be present in 30% or more of the high scoring classifiers. Table 13 provides a list of these potential biomarkers and FIG. 10 is a frequency plot for the identified biomarkers.

Example 3 Naïve Bayesian Classification for NSCLC

From the list of biomarkers identified as useful for discriminating between NSCLC and controls, a panel of ten biomarkers was selected and a naïve Bayes classifier was constructed, see Tables 16 and 18. The class-dependent probability density functions (pdfs), p(x_(i)|c) and p(x_(i)|d), where x_(i) is the log of the measured RFU value for biomarker i, and c and d refer to the control and disease populations, were modeled as log-normal distribution functions characterized by a mean μ and variance σ². The parameters for pdfs of the ten biomarkers are listed in Table 16 and an example of the raw data along with the model fit to a normal pdf is displayed in FIG. 5. The underlying assumption appears to fit the data quite well as evidenced by FIG. 5.

The naïve Bayes classification for such a model is given by the following equation, where p(d) is the prevalence of the disease in the population,

${\ln \left( \frac{p\left( {d\overset{\sim}{x}} \right)}{p\left( {c\overset{\sim}{x}} \right)} \right)} = {{\sum\limits_{i = 1}^{n}{\ln \left( \frac{\sigma_{c,i}}{\sigma_{d,i}} \right)}} - {\frac{1}{2}{\sum\limits_{i = 1}^{n}\left\lbrack {\left( \frac{x_{i} - \mu_{d,i}}{\sigma_{d,i}} \right)^{2} - \left( \frac{x_{i} - \mu_{c,i}}{\sigma_{c,i}} \right)^{2}} \right\rbrack}} + {\ln \left( \frac{p(d)}{1 - {p(d)}} \right)}}$

appropriate to the test and n=10. Each of the terms in the summation is a log-likelihood ratio for an individual marker and the total log-likelihood ratio of a sample {tilde over (x)} being free from the disease of interest (i.e. in this case, NSCLC) versus having the disease is simply the sum of these individual terms plus a term that accounts for the prevalence of the disease. For simplicity, we assume p(d)=0.5 so that

${\ln \left( \frac{p(d)}{1 - {p(d)}} \right)} = 0.$

Given an unknown sample measurement in log(RFU) for each of the ten biomarkers of 6.9, 8.7, 7.9, 9.8, 8.4, 10.6, 7.3, 6.3, 7.3, 8.1, the calculation of the classification is detailed in Table 16. The individual components comprising the log likelihood ratio for disease versus control class are tabulated and can be computed from the parameters in Table 16 and the values of {tilde over (x)}. The sum of the individual log likelihood ratios is −11.584, or a likelihood of being free from the disease versus having the disease of 107,386, where likelihood e^(11.584)=107, 386. The first 3 biomarker values have likelihoods more consistent with the disease group (log likelihood >0) but the remaining 7 biomarkers are all consistently found to favor the control group. Multiplying the likelihoods together gives the same results as that shown above; a likelihood of 107,386 that the unknown sample is free from the disease. In fact, this sample came from the control population in the training set.

Example 4 Greedy Algorithm for Selecting Biomarker Panels for Classifiers

This example describes the selection of biomarkers from Table 1 to form panels that can be used as classifiers in any of the methods described herein. Subsets of the biomarkers in Table 1 were selected to construct classifiers with good performance. This method was also used to determine which potential markers were included as biomarkers in Example 2.

The measure of classifier performance used here is the AUC; a performance of 0.5 is the baseline expectation for a random (coin toss) classifier, a classifier worse than random would score between 0.0 and 0.5, a classifier with better than random performance would score between 0.5 and 1.0. A perfect classifier with no errors would have a sensitivity of 1.0 and a specificity of 1.0. One can apply the methods described in Example 4 to other common measures of performance such as the F-measure, the sum of sensitivity and specificity, or the product of sensitivity and specificity. Specifically one might want to treat sensitivity and specificity with differing weight, so as to select those classifiers which perform with higher specificity at the expense of some sensitivity, or to select those classifiers which perform with higher sensitivity at the expense of some specificity. Since the method described here only involves a measure of “performance”, any weighting scheme which results in a single performance measure can be used. Different applications will have different benefits for true positive and true negative findings, and also different costs associated with false positive findings from false negative findings. For example, screening asymptomatic smokers and the differential diagnosis of benign nodules found on CT will not in general have the same optimal trade-off between specificity and sensitivity. The different demands of the two tests will in general require setting different weighting to positive and negative misclassifications, reflected in the performance measure. Changing the performance measure will in general change the exact subset of markers selected from Table 1 for a given set of data.

For the Bayesian approach to the discrimination of NSCLC samples from control samples described in Example 3, the classifier was completely parameterized by the distributions of biomarkers in the disease and benign training samples, and the list of biomarkers was chosen from Table 1; that is to say, the subset of markers chosen for inclusion determined a classifier in a one-to-one manner given a set of training data.

The greedy method employed here was used to search for the optimal subset of markers from Table 1. For small numbers of markers or classifiers with relatively few markers, every possible subset of markers was enumerated and evaluated in terms of the performance of the classifier constructed with that particular set of markers (see Example 4, Part 2). (This approach is well known in the field of statistics as “best subset selection”; see, e.g., Hastie et al). However, for the classifiers described herein, the number of combinations of multiple markers can be very large, and it was not feasible to evaluate every possible set of 10 markers, as there are 30,045,015 possible combinations that can be generated from a list of only 30 total analytes. Because of the impracticality of searching through every subset of markers, the single optimal subset may not be found; however, by using this approach, many excellent subsets were found, and, in many cases, any of these subsets may represent an optimal one.

Instead of evaluating every possible set of markers, a “greedy” forward stepwise approach may be followed (see, e.g., Dabney A R, Storey J D (2007) Optimality Driven Nearest Centroid Classification from Genomic Data. PLoS ONE 2(10): e1002. doi:10.1371/journal.pone.0001002). Using this method, a classifier is started with the best single marker (based on KS-distance for the individual markers) and is grown at each step by trying, in turn, each member of a marker list that is not currently a member of the set of markers in the classifier. The one marker which scores best in combination with the existing classifier is added to the classifier. This is repeated until no further improvement in performance is achieved. Unfortunately, this approach may miss valuable combinations of markers for which some of the individual markers are not all chosen before the process stops.

The greedy procedure used here was an elaboration of the preceding forward stepwise approach, in that, to broaden the search, rather than keeping just a single candidate classifier (marker subset) at each step, a list of candidate classifiers was kept. The list was seeded with every single marker subset (using every marker in the table on its own). The list was expanded in steps by deriving new classifiers (marker subsets) from the ones currently on the list and adding them to the list. Each marker subset currently on the list was extended by adding any marker from Table 1 not already part of that classifier, and which would not, on its addition to the subset, duplicate an existing subset (these are termed “permissible markers”). Every existing marker subset was extended by every permissible marker from the list. Clearly, such a process would eventually generate every possible subset, and the list would run out of space. Therefore, all the generated classifiers were kept only while the list was less than some predetermined size (often enough to hold all three marker subsets). Once the list reached the predetermined size limit, it became elitist; that is, only those classifiers which showed a certain level of performance were kept on the list, and the others fell off the end of the list and were lost. This was achieved by keeping the list sorted in order of classifier performance; new classifiers which were at least as good as the worst classifier currently on the list were inserted, forcing the expulsion of the current bottom underachiever. One further implementation detail is that the list was completely replaced on each generational step; therefore, every classifier on the list had the same number of markers, and at each step the number of markers per classifier grew by one.

Since this method produced a list of candidate classifiers using different combinations of markers, one may ask if the classifiers can be combined in order to avoid errors which might be made by the best single classifier, or by minority groups of the best classifiers. Such “ensemble” and “committee of experts” methods are well known in the fields of statistical and machine learning and include, for example, “Averaging”, “Voting”, “Stacking”, “Bagging” and “Boosting” (see, e.g., Hastie et al.). These combinations of simple classifiers provide a method for reducing the variance in the classifications due to noise in any particular set of markers by including several different classifiers and therefore information from a larger set of the markers from the biomarker table, effectively averaging between the classifiers. An example of the usefulness of this approach is that it can prevent outliers in a single marker from adversely affecting the classification of a single sample. The requirement to measure a larger number of signals may be impractical in conventional “one marker at a time” antibody assays but has no downside for a fully multiplexed aptamer assay. Techniques such as these benefit from a more extensive table of biomarkers and use the multiple sources of information concerning the disease processes to provide a more robust classification.

The biomarkers selected in Table 1 gave rise to classifiers which perform better than classifiers built with “non-markers” (i.e., proteins having signals that did not meet the criteria for inclusion in Table 1 (as described in Example 2)).

For classifiers containing only one, two, and three markers, all possible classifiers obtained using the biomarkers in Table 1 were enumerated and examined for the distribution of performance compared to classifiers built from a similar table of randomly selected non-markers signals.

In FIG. 11, the AUC was used as the measure of performance; a performance of 0.5 is the baseline expectation for a random (coin toss) classifier. The histogram of classifier performance was compared with the histogram of performance from a similar exhaustive enumeration of classifiers built from a “non-marker” table of 59 non-marker signals; the 59 signals were randomly chosen from aptamers that did not demonstrate differential signaling between control and disease populations.

FIG. 11 shows histograms of the performance of all possible one, two, and three-marker classifiers built from the biomarker parameters in Table 14 for biomarkers that can discriminate between the control group and NSCLC and compares these classifiers with all possible one, two, and three-marker classifiers built using the 59 “non-marker” aptamer RFU signals. FIG. 11A shows the histograms of single marker classifier performance, FIG. 11B shows the histogram of two marker classifier performance, and FIG. 11C shows the histogram of three marker classifier performance.

In FIG. 11, the solid lines represent the histograms of the classifier performance of all one, two, and three-marker classifiers using the biomarker data for smokers and benign pulmonary nodules and NSCLC in Table 14. The dotted lines are the histograms of the classifier performance of all one, two, and three-marker classifiers using the data for controls and NSCLC but using the set of random non-marker signals.

The classifiers built from the markers listed in Table 1 form a distinct histogram, well separated from the classifiers built with signals from the “non-markers” for all onemarker, two-marker, and three-marker comparisons. The performance and AUC score of the classifiers built from the biomarkers in Table 1 also increase faster with the number of markers than do the classifiers built from the non-markers, the separation increases between the marker and non-marker classifiers as the number of markers per classifier increases. All classifiers built using the biomarkers listed in Table 14 perform distinctly better than classifiers built using the “non-markers”.

The distributions of classifier performance show that there are many possible multiple-marker classifiers that can be derived from the set of analytes in Table 1. Although some biomarkers are better than others on their own, as evidenced by the distribution of classifier scores and AUCs for single analytes, it was desirable to determine whether such biomarkers are required to construct high performing classifiers. To make this determination, the behavior of classifier performance was examined by leaving out some number of the best biomarkers. FIG. 12 compares the performance of classifiers built with the full list of biomarkers in Table 1 with the performance of classifiers built with subsets of biomarkers from Table 1 that excluded top-ranked markers.

FIG. 12 demonstrates that classifiers constructed without the best markers perform well, implying that the performance of the classifiers was not due to some small core group of markers and that the changes in the underlying processes associated with disease are reflected in the activities of many proteins. Many subsets of the biomarkers in Table 1 performed close to optimally, even after removing the top 15 of the 59 markers from Table 1. After dropping the 15 top-ranked markers (ranked by KS-distance) from Table 1, the classifier performance increased with the number of markers selected from the table to reach an AUC of almost 0.93, close to the performance of the optimal classifier score of 0.948 selected from the full list of biomarkers.

Finally, FIG. 13 shows how the ROC performance of typical classifiers constructed from the list of parameters in Table 14 according to Example 3. A five analyte classifier was constructed with MMP7, CLIC1, STX1A, CHRDL1, and PA2G4. FIG. 13A shows the performance of the model, assuming independence of these markers, as in Example 3, and FIG. 13B shows the empirical ROC curves generated from the study data set used to define the parameters in Table 14. It can be seen that the performance for a given number of selected markers was qualitatively in agreement, and that quantitative agreement was generally quite good, as evidenced by the AUCs, although the model calculation tends to overestimate classifier performance. This is consistent with the notion that the information contributed by any particular biomarker concerning the disease processes is redundant with the information contributed by other biomarkers provided in Table 1 while the model calculation assumes complete independence. FIG. 13 thus demonstrates that Table 1 in combination with the methods described in Example 3 enable the construction and evaluation of a great many classifiers useful for the discrimination of NSCLC from the control group.

Example 5 Clinical Biomarker Panel

A random forest classifier was built from a panel of biomarkers selected that may be the most appropriate for use in a clinical diagnostic test. Unlike the models selected by the naive Bayes greedy forward algorithm, the random forest classifier does not assume that the biomarker measurements are randomly distributed. Therefore this model can utilize biomarkers from Table 1 that are not effective in the naïve Bayes classifier.

The panel was selected using a backward elimination procedure that utilized the gini importance measure provided by the random forest classifier. The gini importance is a measure of the effectiveness of a biomarker at correctly classifying samples in the training set.

This measure of biomarker importance can be used to eliminate markers that are less vital to the performance of the classifier. The backward elimination procedure was initiated by building a random forest classifier that included all 59 in Table 1. The least important biomarker was then eliminated and a new model was built with the remaining biomakers. This procedure continued until only single biomarkers remained.

The final panel that was selected provided the best balance between the greatest AUC and the lowest number of markers in the model. The panel of 8 biomarkers that satisfied these criteria is composed of the following analytes, MMP12, MMP7, KLK3-SERPINA3, CRP, C9, CNDP1, CA6, and EGFR. A plot of the ROC curve for this biomarker panel is shown in FIG. 14. The sensitivity of this model is 0.70 with a corresponding specificity of 0.89.

Example 6 Biomarkers for the Diagnosis of Cancer

The identification of potential biomarkers for the general diagnosis of cancer was performed. Both case and control samples were evaluated from 3 different types of cancer (lung cancer, mesothelioma, and renal cell carcinoma). Across the sites, inclusion criteria were at least 18 years old with signed informed consent. Both cases and controls were excluded for known malignancy other than the cancer in question.

Lung Cancer. Case and control samples were obtained as described in Example 2. A total of 46 cases and 218 controls were used in this Example.

Pleural Mesothelioma. Case and control samples were obtained from an academic cancer center biorepository to identify potential markers for the differential diagnosis of pleural mesothelioma from benign lung disease, including suspicious radiology findings that were later diagnosed as non-malignant. A total of 124 mesothelioma cases and 138 asbestos exposed controls were used in this Example.

Renal Cell Carcinoma. Case and control samples were obtained from an academic cancer center biorepository from patients with renal cell carcinoma (RCC) and benign masses (BEN). Pre-surgical samples (TP1) were obtained for all subjects. The primary analysis compared outcome data (as recorded in the SEER database field CA Status 1) for the RCC patients with “Evidence of Disease” (EVD) vs “No Evidence of Disease” (NED) documented through clinical follow-up. A total of 38 EVD cases and 104 NED controls were used in this Example.

A final list of cancer biomarkers was identified by combining the sets of biomarkers considered for each of the 3 different cancer studies. Bayesian classifiers that used biomarker sets of increasing size were successively constructed using a greedy algorithm (as described in greater detail in Section 6.2 of this Example). The sets (or panels) of biomarkers that were useful for diagnosing cancer in general among the different sites and types of cancer were compiled as a function of set (or panel) size and analyzed for their performance. This analysis resulted in the list of 23 cancer biomarkers shown in Table 19, each of which was present in at least one of these successive marker sets, which ranged in size from three to ten markers. As an illustrative example, we describe the generation of a specific panel composed of ten cancer biomarkers, which is shown in Table 32.

6.1 Naïve Bayesian Classification for Cancer

From the list of biomarkers in Table 1, a panel of ten potential cancer biomarkers was selected using a greedy algorithm for biomarker selection, as outlined in Section 6.2 of this Example. A distinct naïve Bayes classifier was constructed for each of the 3. The class-dependent probability density functions (pdfs), p(x_(i)|c) and p(x_(i)|d), where x_(i) is the log of the measured RFU value for biomarker i, and c and d refer to the control and disease populations, were modeled as log-normal distribution functions characterized by a mean p and variance σ². The parameters for pdfs of the 3 models composed of the ten potential biomarkers are listed in Table 31.

The naïve Bayes classification for such a model is given by the following equation, where p(d) is the prevalence of the disease in the population

${\ln \left( \frac{p\left( {d\overset{\sim}{x}} \right)}{p\left( {c\overset{\sim}{x}} \right)} \right)} = {{\sum\limits_{i = 1}^{n}{\ln \left( \frac{\sigma_{c,i}}{\sigma_{d,i}} \right)}} - {\frac{1}{2}{\sum\limits_{i = 1}^{n}\left\lbrack {\left( \frac{x_{i} - \mu_{d,i}}{\sigma_{d,i}} \right)^{2} - \left( \frac{x_{i} - \mu_{c,i}}{\sigma_{c,i}} \right)^{2}} \right\rbrack}} + {\ln \left( \frac{p(d)}{1 - {p(d)}} \right)}}$

appropriate to the test and n=10. Each of the terms in the summation is a log-likelihood ratio for an individual marker and the total log-likelihood ratio of a sample being free from the disease interest (i.e., in this case, each particular disease from the 3 different cancer types) versus having the disease is simply the sum of these individual terms plus a term that accounts for the prevalence of the disease. For simplicity, we assume p(d)=0.5 so that

${\ln \left( \frac{p(d)}{1 - {p(d)}} \right)} = 0.$

Given an unknown sample measurement in log(RFU) for each of the ten biomarkers of 9.5, 8.8, 7.8, 8.3, 9.4, 7.0, 7.9, 6.3, 7.7, 10.6, the calculation of the classification is detailed in Table 32. The individual components comprising the log likelihood ratio for disease versus control class are tabulated and can be computed from the parameters in Table 31 and the values of The sum of the individual log likelihood ratios is −3.326, or a likelihood of being free from the disease versus having the disease of 28, where likelihood e^(3.326)=28. The first 4 biomarker values have likelihoods more consistent with the disease group (log likelihood >0) but the remaining 6 biomarkers are all consistently found to favor the control group. Multiplying the likelihoods together gives the same results as that shown above; a likelihood of 28 that the unknown sample is free from the disease. In fact, this sample came from the control population in the renal cell carcinoma training set.

6.1 Naïve Bayesian Classification for Cancer

From the list of biomarkers in Table 1, a panel of ten potential cancer biomarkers was selected using a greedy algorithm for biomarker selection, as outlined in Section 6.2 of this Example. A distinct naïve Bayes classifier was constructed for each of the 3 different cancer types. The class-dependent probability density functions (pdfs), p(x_(i)|c) and p(x_(i)|d), where x_(i) is the log of the measured RFU value for biomarker i, and c and d refer to the control and disease populations, were modeled as log-normal distribution functions characterized by a mean μ and variance σ². The parameters for pdfs of the 3 models composed of the ten potential biomarkers are listed in Table 31.

The naïve Bayes classification for such a model is given by the following equation, where p(d) is the prevalence of the disease in the population,

${\ln \left( \frac{p\left( {d\overset{\sim}{x}} \right)}{p\left( {c\overset{\sim}{x}} \right)} \right)} = {{\sum\limits_{i = 1}^{n}{\ln \left( \frac{\sigma_{c,i}}{\sigma_{d,i}} \right)}} - {\frac{1}{2}{\sum\limits_{i = 1}^{n}\left\lbrack {\left( \frac{x_{i} - \mu_{d,i}}{\sigma_{d,i}} \right)^{2} - \left( \frac{x_{i} - \mu_{c,i}}{\sigma_{c,i}} \right)^{2}} \right\rbrack}} + {\ln \left( \frac{p(d)}{1 - {p(d)}} \right)}}$

appropriate to the test and n=10. Each of the terms in the summation is a log-likelihood ratio for an individual marker and the total log-likelihood ratio of a sample x being free from the disease interest (i.e., in this case, each particular disease from the 3 different cancer types) versus having the disease is simply the sum of these individual terms plus a term that accounts for the prevalence of the disease. For simplicity, we assume p(d)=0.5 so that

${\ln \left( \frac{p(d)}{1 - {p(d)}} \right)} = 0.$

Given an unknown sample measurement in log(RFU) for each of the ten biomarkers of 9.5, 8.8, 7.8, 8.3, 9.4, 7.0, 7.9, 6.3, 7.7, 10.6, the calculation of the classification is detailed in Table 32. The individual components comprising the log likelihood ratio for disease versus control class are tabulated and can be computed from the parameters in Table 31 and the values of x. The sum of the individual log likelihood ratios is −3.326, or a likelihood of being free from the disease versus having the disease of 28, where likelihood e^(3.326)=28. Only 4 of the biomarker values have likelihoods more consistent with the disease group (log likelihood >0) but the remaining 6 biomarkers are all consistently found to favor the control group. Multiplying the likelihoods together gives the same results as that shown above; a likelihood of 28 that the unknown sample is free from the disease. In fact, this sample came from the control population in the NSCLC training set.

6.2 Greedy Algorithm for Selecting Cancer Biomarker Panels for Classifiers Part 1

Subsets of the biomarkers in Table 1 were selected to construct potential classifiers that could be used to determine which of the markers could be used as general cancer biomarkers to detect cancer.

Given a set of markers, a distinct model was trained for each of the 3 cancer studies, so a global measure of performance was required to select a set of biomarkers that was able to classify simultaneously many different types of cancer. The measure of classifier performance used here was the mean of the area under ROC curve across all naïve Bayes classifiers. The ROC curve is a plot of a single classifier true positive rate (sensitivity) versus the false positive rate (1-specificity). The area under the ROC curve (AUC) ranges from 0 to 1.0, where an AUC of 1.0 corresponds to perfect classification and an AUC of 0.5 corresponds to random (coin toss) classifier. One can apply other common measures of performance such as the F-measure or the sum or product of sensitivity and specificity. Specifically, one might want to treat sensitivity and specificity with differing weight, in order to select those classifiers that perform with higher specificity at the expense of some sensitivity, or to select those classifiers which perform with higher sensitivity at the expense of specificity. We chose to use the AUC because it encompasses all combinations of sensitivity and specificity in a single measure. Different applications will have different benefits for true positive and true negative findings, and will have different costs associated with false positive findings from false negative findings. Changing the performance measure may change the exact subset of markers selected for a given set of data.

For the Bayesian approach to the discrimination of cancer samples from control samples described in Section 6.1 of this Example, the classifier was completely parameterized by the distributions of biomarkers in each of the 3 cancer studies, and the list of biomarkers was chosen from Table 19. That is to say, the subset of markers chosen for inclusion determined a classifier in a one-to-one manner given a set of training data.

The greedy method employed here was used to search for the optimal subset of markers from Table 1. For small numbers of markers or classifiers with relatively few markers, every possible subset of markers was enumerated and evaluated in terms of the performance of the classifier constructed with that particular set of markers (see Example 4). (This approach is well known in the field of statistics as “best subset selection”; see, e.g., Hastie et al). However, for the classifiers described herein, the number of combinations of multiple markers can be very large, and it was not feasible to evaluate every possible set of 10 markers, as there are 30,045,015 possible combinations that can be generated from a list of only 30 total analytes. Because of the impracticality of searching through every subset of markers, the single optimal subset may not be found; however, by using this approach, many excellent subsets were found, and, in many cases, any of these subsets may represent an optimal one.

Instead of evaluating every possible set of markers, a “greedy” forward stepwise approach may be followed (see, e.g., Dabney A R, Storey J D (2007) Optimality Driven Nearest Centroid Classification from Genomic Data. PLoS ONE 2(10): e1002. doi:10.1371/journal.pone.0001002). Using this method, a classifier is started with the best single marker (based on KS-distance for the individual markers) and is grown at each step by trying, in turn, each member of a marker list that is not currently a member of the set of markers in the classifier. The one marker that scores the best in combination with the existing classifier is added to the classifier. This is repeated until no further improvement in performance is achieved. Unfortunately, this approach may miss valuable combinations of markers for which some of the individual markers are not all chosen before the process stops.

The greedy procedure used here was an elaboration of the preceding forward stepwise approach, in that, to broaden the search, rather than keeping just a single marker subset at each step, a list of candidate marker sets was kept. The list was seeded with a list of single markers. The list was expanded in steps by deriving new marker subsets from the ones currently on the list and adding them to the list. Each marker subset currently on the list was extended by adding any marker from Table 1 not already part of that classifier, and which would not, on its addition to the subset, duplicate an existing subset (these are termed “permissible markers”). Each time a new set of markers was defined, a set of classifiers composed of one for each cancer study was trained using these markers, and the global performance was measured via the mean AUC across all 3 studies. To avoid potential over fitting, the AUC for each cancer study model was calculated via a ten-fold cross validation procedure. Every existing marker subset was extended by every permissible marker from the list. Clearly, such a process would eventually generate every possible subset, and the list would run out of space. Therefore, all the generated marker sets were kept only while the list was less than some predetermined size. Once the list reached the predetermined size limit, it became elitist; that is, only those classifier sets which showed a certain level of performance were kept on the list, and the others fell off the end of the list and were lost. This was achieved by keeping the list sorted in order of classifier set performance; new marker sets whose classifiers were globally at least as good as the worst set of classifiers currently on the list were inserted, forcing the expulsion of the current bottom underachieving classifier sets. One further implementation detail is that the list was completely replaced on each generational step; therefore, every marker set on the list had the same number of markers, and at each step the number of markers per classifier grew by one.

In one embodiment, the set (or panel) of biomarkers useful for constructing classifiers for diagnosing general cancer from non-cancer is based on the mean AUC for the particular combination of biomarkers used in the classification scheme. We identified many combinations of biomarkers derived from the markers in Table 19 that were able to effectively classify different cancer samples from controls. Representative panels are set forth in Tables 22-29, which set forth a series of 100 different panels of 3-10 biomarkers, which have the indicated mean cross validation (CV) AUC for each panel. The total number of occurrences of each marker in each of these panels is indicated at the bottom of each table.

The biomarkers selected in Table 19 gave rise to classifiers that perform better than classifiers built with “non-markers.” In FIG. 15, we display the performance of our ten biomarker classifiers compared to the performance of other possible classifiers.

FIG. 15A shows the distribution of mean AUCs for classifiers built from randomly sampled sets of ten “non-markers” taken from the entire set of 23 present in all 3 studies, excluding the ten markers in Table 19. The performance of the ten potential cancer biomarkers is displayed as a vertical dashed line. This plot clearly shows that the performance of the ten potential biomarkers is well beyond the distribution of other marker combinations.

FIG. 15B displays a similar distribution as FIG. 15A, however the randomly sampled sets were restricted to the 49 biomarkers from Table 1 that were not selected by the greedy biomarker selection procedure for ten analyte classifiers. This plot demonstrates that the ten markers chosen by the greedy algorithm represent a subset of biomarkers that generalize to other types of cancer far better than classifiers built with the remaining 49 biomarkers.

Finally, FIG. 16 shows the classifier ROC curve for each of the 3 cancer studies classifiers. The foregoing embodiments and examples are intended only as examples. No particular embodiment, example, or element of a particular embodiment or example is to be construed as a critical, required, or essential element or feature of any of the claims. Further, no element described herein is required for the practice of the appended claims unless expressly described as “essential” or “critical.” Various alterations, modifications, substitutions, and other variations can be made to the disclosed embodiments without departing from the scope of the present application, which is defined by the appended claims. The specification, including the figures and examples, is to be regarded in an illustrative manner, rather than a restrictive one, and all such modifications and substitutions are intended to be included within the scope of the application. Accordingly, the scope of the application should be determined by the appended claims and their legal equivalents, rather than by the examples given above. For example, steps recited in any of the method or process claims may be executed in any feasible order and are not limited to an order presented in any of the embodiments, the examples, or the claims. Further, in any of the aforementioned methods, one or more biomarkers of Table 1 or Table 19 can be specifically excluded either as an individual biomarker or as a biomarker from any panel.

TABLE 1 Cancer Biomarkers Column #2 Column #1 Biomarker Designation Column #3 Column #4 Column #5 Column #6 Biomarker # Entrez Gene Symbol(s) Entrez Gene ID SwissProt ID Public Name Direction 1 AHSG 197 P02765 α2-HS-Glycoprotein Down 2 AKR7A2 8574 O43488 Aflatoxin B1 aldehyde Up reductase 3 AKT3 10000 Q9Y243 PKB γ Up 4 ASGR1 432 P07306 ASGPR1 Down 5 BDNF 627 P23560 BDNF Down 6 BMP1 649 P13497 BMP-1 Down 7 BMPER 168667 Q8N8U9 BMPER Down 8 C9 735 P02748 C9 Up 9 CA6 765 P23280 Carbonic anhydrase VI Down 10 CAPG 822 P40121 CapG Down 11 CDH1 999 P12830 Cadherin-1 Down 12 CHRDL1 91851 Q9BU40 Chordin-Like 1 Up 13 CKB-CKM- 1152; 1158 P12277; P06732 CK-MB Down 14 CLIC1 1192 O00299 chloride intracellular Up channel 1 15 CMA1 1215 P23946 Chymase Down 16 CNTN1 1272 Q12860 Contactin-1 Down 17 COL18A1 80781 P39060 Endostatin Up 18 CRP 1401 P02741 CRP Up 19 CTSL2 1515 O60911 Cathepsin V Down 20 DDC 1644 P20711 dopa decarboxylase Down 21 EGFR 1956 P00533 ERBB1 Down 22 FGA-FGB-FGG 2243; 2244; 2266 P02671; P02675; P02679 D-dimer Up 23 FN1 2335 P02751 Fibronectin FN1.4 Down 24 GHR 2690 P10912 Growth hormone receptor Down 25 GPI 2821 P06744 glucose phosphate isomerase Up 26 HMGB1 3146 P09429 HMG-1 Up 27 HNRNPAB 3182 Q99729 hnRNP A/B Up 28 HP 3240 P00738 Haptoglobin, Mixed Up Type 29 HSP90AA1 3320 P07900 HSP 90α Up 30 HSPA1A 3303 P08107 HSP 70 Up 31 IGFBP2 3485 P18065 IGFBP-2 Up 32 IGFBP4 3487 P22692 IGFBP-4 Up 33 IL12B-IL23A  3593; 51561 P29460; Q9NPF7 IL-23 Up 34 ITIH4 3700 Q14624 Inter-α-trypsin inhibitor Up heavy chain H4 35 KIT 3815 P10721 SCF sR Down 36 KLK3-SERPINA3 354; 12  P07288; P01011 PSA-ACT Up 37 L1CAM 3897 P32004 NCAM-L1 Down 38 LRIG3 121227 Q6UXM1 LRIG3 Down 39 MMP12 4321 P39900 MMP-12 Up 40 MMP7 4316 P09237 MMP-7 Up 41 NME2 4831 P22392 NDP kinase B Up 42 PA2G4 5036 Q9UQ80 ErbB3 binding protein Up Ebp1 43 PLA2G7 7941 Q13093 LpPLA2/PAFAH Down 44 PLAUR 5329 Q03405 suPAR Up 45 PRKACA 5566 P17612 PRKA C-α Up 46 PRKCB 5579 P05771 PKC-β-II Down 47 PROK1 84432 P58294 EG-VEGF Down 48 PRSS2 5645 P07478 Trypsin-2 Up 49 PTN 5764 P21246 Pleiotrophin Up 50 SERPINA1 5265 P01009 α1-Antitrypsin Up 51 STC1 6781 P52823 Stanniocalcin-1 Up 52 STX1A 6804 Q16623 Syntaxin 1A Down 53 TACSTD2 4070 P09758 GA733-1 protein Down 54 TFF3 7033 Q07654 Trefoil factor 3 Up 55 TGFBI 7045 Q15582 βIGH3 Down 56 TPI1 7167 P60174 Triosephosphate isomerase Up 57 TPT1 7178 P13693 Fortilin Up 58 YWHAG 7532 P61981 14-3-3 protein γ Up 59 YWHAH 7533 Q04917 14-3-3 protein eta Up

TABLE 2 Panels of 1 Biomarker Markers CV AUC 1 YWHAG 0.840 2 MMP7 0.804 3 CLIC1 0.803 4 MMP12 0.773 5 STX1A 0.771 6 C9 0.769 7 LRIG3 0.769 8 EGFR 0.767 9 TPT1 0.760 10 CMA1 0.758 11 YWHAH 0.756 12 GPI 0.752 13 BMP1 0.751 14 DDC 0.747 15 NME2 0.745 16 IGFBP2 0.743 17 FGA-FGB-FGG 0.741 18 CAPG 0.738 19 AKR7A2 0.733 20 HNRNPAB 0.730 21 CDH1 0.728 22 HSP90AA1 0.726 23 CKB-CKM 0.724 24 CRP 0.724 25 PTN 0.723 26 BMPER 0.721 27 TPI1 0.720 28 TGFBI 0.720 29 KIT 0.717 30 HP 0.715 31 KLK3-SERPINA3 0.713 32 PLAUR 0.711 33 GHR 0.705 34 CA6 0.705 35 PRKACA 0.704 36 COL18A1 0.701 37 HMGB1 0.700 38 IGFBP4 0.698 39 AKT3 0.697 40 AHSG 0.697 41 CTSL2 0.694 42 TACSTD2 0.690 43 FN1 0.690 44 IL12B-IL23A 0.690 45 BDNF 0.689 46 L1CAM 0.688 47 SERPINA1 0.688 48 PROK11 0.684 49 PRKCB 0.684 50 STC1 0.682 51 CHRDL1 0.679 52 TFF3 0.678 53 PRSS2 0.663 54 ASGR1 0.660 55 HSPA1A 0.658 56 PA2G4 0.655 57 CNTN1 0.648 58 ITIH4 0.635 59 PLA2G7 0.631

TABLE 3 Panels of 2 Biomarkers Markers CV AUC 1 MMP7 YWHAG 0.878 2 C9 YWHAG 0.876 3 STX1A YWHAG 0.874 4 MMP7 CLIC1 0.874 5 LRIG3 YWHAG 0.871 6 KLK3-SERPINA3 YWHAG 0.867 7 YWHAG CRP 0.867 8 BMP1 YWHAG 0.866 9 MMP12 CLIC1 0.865 10 TGFBI YWHAG 0.864 11 KLK3-SERPINA3 CLIC1 0.863 12 YWHAG L1CAM 0.863 13 STX1A CLIC1 0.863 14 SERPINA1 YWHAG 0.862 15 CMA1 YWHAG 0.862 16 NME2 FGA-FGB-FGG 0.861 17 CA6 YWHAG 0.859 18 MMP7 AKR7A2 0.859 19 DDC YWHAG 0.858 20 C9 CLIC1 0.857 21 MMP7 NME2 0.857 22 CKB-CKM YWHAG 0.857 23 FGA-FGB-FGG CLIC1 0.856 24 BMP1 CLIC1 0.856 25 EGFR YWHAG 0.856 26 AHSG YWHAG 0.855 27 YWHAG MMP12 0.855 28 MMP7 TPI1 0.855 29 KIT YWHAG 0.855 30 LRIG3 CLIC1 0.854 31 HP YWHAG 0.854 32 PLAUR YWHAG 0.854 33 CMA1 CLIC1 0.853 34 BDNF YWHAG 0.853 35 EGFR CLIC1 0.853 36 MMP7 TPT1 0.852 37 YWHAG CLIC1 0.851 38 PTN YWHAG 0.850 39 BDNF CLIC1 0.849 40 IGFBP2 YWHAG 0.849 41 MMP7 GPI 0.849 42 CNTN1 YWHAG 0.849 43 BMPER YWHAG 0.848 44 YWHAG FGA-FGB-FGG 0.847 45 MMP7 HNRNPAB 0.847 46 C9 GPI 0.847 47 YWHAG GPI 0.846 48 L1CAM MMP12 0.846 49 YWHAG ITIH4 0.846 50 GHR YWHAG 0.846 51 YWHAG HNRNPAB 0.846 52 MMP7 CMA1 0.846 53 C9 NME2 0.845 54 MMP7 LRIG3 0.845 55 IGFBP2 CLIC1 0.845 56 COL18A1 YWHAG 0.845 57 CHRDL1 CLIC1 0.845 58 CDH1 MMP7 0.844 59 PLAUR CLIC1 0.844 60 TPI1 FGA-FGB-FGG 0.844 61 CHRDL1 YWHAG 0.844 62 MMP7 PRKACA 0.844 63 C9 AKR7A2 0.843 64 YWHAG PLA2G7 0.843 65 KLK3-SERPINA3 TPT1 0.843 66 BMP1 GPI 0.843 67 KLK3-SERPINA3 MMP7 0.842 68 C9 TPT1 0.842 69 COL18A1 CLIC1 0.842 70 YWHAG AKR7A2 0.842 71 YWHAG STC1 0.842 72 MMP7 TGFBI 0.842 73 AKR7A2 MMP12 0.842 74 MMP7 YWHAH 0.842 75 HMGB1 MMP7 0.841 76 TPT1 FGA-FGB-FGG 0.841 77 GHR CLIC1 0.841 78 KLK3-SERPINA3 STX1A 0.840 79 LRIG3 TPT1 0.840 80 STX1A MMP12 0.840 81 YWHAG PRSS2 0.840 82 DDC CLIC1 0.840 83 CRP CLIC1 0.840 84 HMGB1 YWHAG 0.840 85 STX1A TPT1 0.839 86 CDH1 YWHAG 0.839 87 STX1A GPI 0.839 88 KLK3-SERPINA3 NME2 0.838 89 LRIG3 YWHAH 0.838 90 AKR7A2 FGA-FGB-FGG 0.838 91 C9 HNRNPAB 0.837 92 TACSTD2 YWHAG 0.837 93 YWHAG TPI1 0.837 94 STX1A NME2 0.836 95 KLK3-SERPINA3 AKR7A2 0.836 96 LRIG3 AKR7A2 0.836 97 NME2 MMP12 0.836 98 CAPG CLIC1 0.836 99 YWHAG NME2 0.836 100 MMP7 STX1A 0.835

TABLE 4 Panels of 3 Biomarkers Markers CV AUC 1 KLK3-SERPINA3 MMP7 CLIC1 0.896 2 KLK3-SERPINA3 STX1A CLIC1 0.895 3 KLK3-SERPINA3 STX1A YWHAG 0.895 4 MMP7 C9 YWHAG 0.895 5 MMP7 YWHAG CLIC1 0.894 6 C9 STX1A YWHAG 0.893 7 MMP7 LRIG3 YWHAG 0.893 8 MMP7 TGFBI YWHAG 0.893 9 MMP7 CMA1 CLIC1 0.893 10 BDNF MMP7 CLIC1 0.892 11 MMP7 GHR CLIC1 0.892 12 CDH1 MMP7 YWHAG 0.892 13 BDNF C9 CLIC1 0.892 14 STX1A YWHAG CRP 0.892 15 MMP7 YWHAG TPI1 0.892 16 MMP7 STX1A YWHAG 0.892 17 TGFBI STX1A YWHAG 0.891 18 LRIG3 YWHAG CRP 0.891 19 MMP7 YWHAG L1CAM 0.891 20 MMP7 YWHAG PA2G4 0.891 21 C9 LRIG3 YWHAG 0.890 22 STX1A MMP12 CLIC1 0.890 23 MMP7 LRIG3 CLIC1 0.890 24 KLK3-SERPINA3 MMP7 YWHAG 0.890 25 MMP7 BMP1 CLIC1 0.890 26 BDNF STX1A CLIC1 0.890 27 MMP7 STX1A CLIC1 0.889 28 MMP7 BMP1 YWHAG 0.889 29 HMGB1 MMP7 YWHAG 0.889 30 SERPINA1 STX1A YWHAG 0.889 31 MMP7 YWHAG GPI 0.889 32 MMP7 CMA1 YWHAG 0.889 33 MMP7 YWHAG NME2 0.889 34 MMP7 C9 CLIC1 0.889 35 C9 CMA1 YWHAG 0.888 36 MMP7 YWHAG CRP 0.888 37 KLK3-SERPINA3 CNTN1 YWHAG 0.888 38 MMP7 YWHAG AKR7A2 0.887 39 MMP7 ITIH4 CLIC1 0.887 40 CDH1 MMP7 CLIC1 0.887 41 KLK3-SERPINA3 MMP7 AKR7A2 0.887 42 MMP7 GHR YWHAG 0.887 43 KLK3-SERPINA3 CHRDL1 CLIC1 0.887 44 KLK3-SERPINA3 LRIG3 YWHAG 0.887 45 BMP1 STX1A CLIC1 0.887 46 C9 STX1A CLIC1 0.887 47 MMP7 GPI CLIC1 0.887 48 TGFBI LRIG3 YWHAG 0.886 49 IGFBP2 MMP7 YWHAG 0.886 50 MMP7 CKB-CKM YWHAG 0.886 51 LRIG3 STX1A YWHAG 0.886 52 GHR STX1A CLIC1 0.886 53 MMP7 DDC YWHAG 0.886 54 BMP1 STX1A YWHAG 0.886 55 MMP7 DDC CLIC1 0.886 56 C9 CHRDL1 CLIC1 0.885 57 MMP7 C9 AKR7A2 0.885 58 BDNF MMP7 YWHAG 0.885 59 KIT MMP7 YWHAG 0.885 60 MMP7 TGFBI CLIC1 0.885 61 BDNF IGFBP2 CLIC1 0.885 62 MMP7 YWHAG ITIH4 0.885 63 MMP7 YWHAG HNRNPAB 0.885 64 KLK3-SERPINA3 LRIG3 CLIC1 0.885 65 MMP7 HP YWHAG 0.885 66 HMGB1 MMP7 CLIC1 0.885 67 MMP7 YWHAG PLA2G7 0.885 68 CHRDL1 CMA1 CLIC1 0.885 69 STX1A YWHAG L1CAM 0.885 70 MMP7 CMA1 NME2 0.885 71 BMP1 MMP12 CLIC1 0.884 72 C9 CHRDL1 YWHAG 0.884 73 KLK3-SERPINA3 CMA1 CLIC1 0.884 74 EGFR MMP7 CLIC1 0.884 75 STX1A YWHAG CLIC1 0.884 76 MMP7 AHSG YWHAG 0.884 77 IGFBP2 MMP7 CLIC1 0.884 78 MMP7 TPT1 YWHAG 0.884 79 KLK3-SERPINA3 COL18A1 CLIC1 0.884 80 EGFR MMP7 YWHAG 0.884 81 C9 YWHAG L1CAM 0.884 82 KLK3-SERPINA3 MMP7 TPI1 0.884 83 KLK3-SERPINA3 BDNF CLIC1 0.884 84 MMP7 CA6 YWHAG 0.884 85 BMP1 YWHAG CRP 0.883 86 MMP7 CMA1 TPI1 0.883 87 KLK3-SERPINA3 MMP7 NME2 0.883 88 BDNF C9 YWHAG 0.883 89 AHSG STX1A YWHAG 0.883 90 C9 MMP12 CLIC1 0.883 91 C9 BMP1 YWHAG 0.883 92 KLK3-SERPINA3 STX1A TPT1 0.883 93 CNTN1 C9 YWHAG 0.883 94 C9 CA6 YWHAG 0.883 95 CA6 STX1A YWHAG 0.883 96 MMP7 CNTN1 YWHAG 0.883 97 KLK3-SERPINA3 STX1A NME2 0.883 98 MMP7 HNRNPAB CLIC1 0.883 99 MMP7 SERPINA1 YWHAG 0.883 100 TGFBI CMA1 YWHAG 0.883

TABLE 5 Panels of 4 Biomarkers Markers CV AUC 1 KLK3- MMP7 STX1A CLIC1 0.911 SERPINA3 2 KLK3- BDNF STX1A CLIC1 0.910 SERPINA3 3 BDNF C9 CHRDL1 CLIC1 0.909 4 BDNF C9 STX1A CLIC1 0.908 5 MMP7 C9 YWHAG TPI1 0.908 6 MMP7 C9 YWHAG CLIC1 0.908 7 MMP7 GHR STX1A CLIC1 0.907 8 KLK3- MMP7 CMA1 CLIC1 0.907 SERPINA3 9 KLK3- BDNF MMP7 CLIC1 0.907 SERPINA3 10 MMP7 C9 CMA1 CLIC1 0.907 11 BDNF MMP7 YWHAG CLIC1 0.907 12 CDH1 MMP7 C9 YWHAG 0.907 13 KLK3- MMP7 LRIG3 CLIC1 0.906 SERPINA3 14 MMP7 GHR CMA1 CLIC1 0.906 15 MMP7 C9 YWHAG NME2 0.906 16 CDH1 MMP7 STX1A YWHAG 0.906 17 MMP7 C9 LRIG3 YWHAG 0.905 18 MMP7 C9 YWHAG GPI 0.905 19 CDH1 MMP7 STX1A CLIC1 0.905 20 BDNF MMP7 GHR CLIC1 0.905 21 MMP7 STX1A YWHAG CLIC1 0.905 22 BDNF MMP7 LRIG3 CLIC1 0.905 23 BDNF MMP7 STX1A CLIC1 0.905 24 MMP7 LRIG3 YWHAG CLIC1 0.905 25 BDNF MMP7 CMA1 CLIC1 0.905 26 MMP7 C9 TGFBI YWHAG 0.904 27 CDH1 MMP7 LRIG3 YWHAG 0.904 28 KLK3- CHRDL1 CMA1 CLIC1 0.904 SERPINA3 29 TGFBI STX1A YWHAG CRP 0.904 30 BDNF MMP7 C9 CLIC1 0.904 31 KLK3- CHRDL1 STX1A CLIC1 0.904 SERPINA3 32 KLK3- MMP7 STX1A YWHAG 0.904 SERPINA3 33 KLK3- BMP1 STX1A CLIC1 0.904 SERPINA3 34 MMP7 STX1A YWHAG NME2 0.904 35 BDNF MMP7 TGFBI CLIC1 0.904 36 MMP7 C9 YWHAG L1CAM 0.904 37 MMP7 TGFBI LRIG3 YWHAG 0.904 38 KLK3- BDNF CHRDL1 CLIC1 0.904 SERPINA3 39 KLK3- GHR STX1A CLIC1 0.904 SERPINA3 40 KLK3- LRIG3 CHRDL1 CLIC1 0.904 SERPINA3 41 KLK3- MMP7 LRIG3 YWHAG 0.904 SERPINA3 42 KLK3- LRIG3 STX1A CLIC1 0.904 SERPINA3 43 MMP7 GHR BMP1 CLIC1 0.904 44 CDH1 MMP7 CMA1 CLIC1 0.904 45 LRIG3 STX1A YWHAG CRP 0.904 46 MMP7 GHR YWHAG CLIC1 0.904 47 BDNF GHR STX1A CLIC1 0.904 48 MMP7 C9 CMA1 YWHAG 0.904 49 MMP7 LRIG3 GPI CLIC1 0.904 50 MMP7 C9 STX1A YWHAG 0.903 51 BDNF MMP7 GPI CLIC1 0.903 52 KLK3- MMP7 YWHAG CLIC1 0.903 SERPINA3 53 MMP7 TGFBI STX1A YWHAG 0.903 54 KLK3- COL18A1 STX1A CLIC1 0.903 SERPINA3 55 MMP7 TGFBI CMA1 CLIC1 0.903 56 MMP7 C9 YWHAG PA2G4 0.903 57 MMP7 C9 YWHAG AKR7A2 0.903 58 KLK3- MMP7 BMP1 CLIC1 0.903 SERPINA3 59 MMP7 GHR LRIG3 CLIC1 0.903 60 MMP7 GHR C9 CLIC1 0.903 61 MMP7 BMP1 YWHAG CLIC1 0.903 62 KLK3- MMP7 GHR CLIC1 0.903 SERPINA3 63 BDNF STX1A MMP12 CLIC1 0.903 64 MMP7 LRIG3 YWHAG CRP 0.903 65 BDNF IGFBP2 MMP7 CLIC1 0.903 66 GHR STX1A CRP CLIC1 0.903 67 BDNF STX1A CRP CLIC1 0.902 68 KLK3- CNTN1 BMP1 CLIC1 0.902 SERPINA3 69 BDNF MMP7 C9 YWHAG 0.902 70 CDH1 MMP7 TGFBI YWHAG 0.902 71 BDNF IGFBP2 STX1A CLIC1 0.902 72 KLK3- MMP7 NME2 CLIC1 0.902 SERPINA3 73 KLK3- MMP7 TPI1 CLIC1 0.902 SERPINA3 74 MMP7 LRIG3 YWHAG NME2 0.902 75 KLK3- EGFR STX1A CLIC1 0.902 SERPINA3 76 BDNF IGFBP2 LRIG3 CLIC1 0.902 77 MMP7 CMA1 YWHAG CLIC1 0.902 78 MMP7 GHR STX1A YWHAG 0.902 79 HMGB1 MMP7 C9 YWHAG 0.902 80 IGFBP2 MMP7 CMA1 CLIC1 0.902 81 MMP7 GHR GPI CLIC1 0.902 82 KLK3- STX1A YWHAG CLIC1 0.902 SERPINA3 83 KLK3- SERPINA1 STX1A YWHAG 0.902 SERPINA3 84 BDNF PLAUR LRIG3 CLIC1 0.902 85 BDNF TGFBI STX1A CLIC1 0.902 86 BDNF MMP7 ITIH4 CLIC1 0.902 87 MMP7 LRIG3 YWHAG GPI 0.902 88 MMP7 BMP1 YWHAG GPI 0.902 89 C9 CHRDL1 CMA1 CLIC1 0.902 90 MMP7 BMP1 CMA1 CLIC1 0.902 91 KLK3- MMP7 CNTN1 CLIC1 0.902 SERPINA3 92 MMP7 CMA1 HNRNPAB CLIC1 0.902 93 KLK3- LRIG3 STX1A YWHAG 0.902 SERPINA3 94 BDNF LRIG3 STX1A CLIC1 0.902 95 MMP7 TGFBI CMA1 YWHAG 0.902 96 MMP7 LRIG3 YWHAG TPI1 0.902 97 MMP7 CMA1 NME2 CLIC1 0.902 98 MMP7 GHR CRP CLIC1 0.902 99 C9 LRIG3 CHRDL1 CLIC1 0.902 100 MMP7 LRIG3 STX1A CLIC1 0.902

TABLE 6 Panels of 5 Biomarkers Markers CV AUC 1 TGFBI LRIG3 CHRDL1 NME2 CRP 0.922 2 KLK3-SERPINA3 BDNF MMP7 STX1A CLIC1 0.920 3 BDNF MMP7 GHR STX1A CLIC1 0.919 4 BDNF MMP7 C9 YWHAG CLIC1 0.918 5 KLK3-SERPINA3 MMP7 GHR STX1A CLIC1 0.918 6 BDNF C9 CHRDL1 AHSG CLIC1 0.918 7 CDH1 MMP7 GHR STX1A CLIC1 0.918 8 KLK3-SERPINA3 MMP7 STX1A NME2 CLIC1 0.918 9 MMP7 GHR STX1A YWHAG CLIC1 0.918 10 MMP7 GHR STX1A GPI CLIC1 0.918 11 KLK3-SERPINA3 MMP7 LRIG3 STX1A CLIC1 0.917 12 BDNF MMP7 GHR GPI CLIC1 0.917 13 BDNF MMP7 STX1A YWHAG CLIC1 0.917 14 BDNF TGFBI LRIG3 CHRDL1 CLIC1 0.917 15 KLK3-SERPINA3 BDNF LRIG3 STX1A CLIC1 0.917 16 KLK3-SERPINA3 BDNF C9 STX1A CLIC1 0.917 17 BDNF MMP7 LRIG3 YWHAG CLIC1 0.917 18 BDNF GHR C9 STX1A CLIC1 0.916 19 BDNF IGFBP2 LRIG3 CRP CLIC1 0.916 20 KLK3-SERPINA3 BDNF CHRDL1 STX1A CLIC1 0.916 21 KLK3-SERPINA3 CDH1 MMP7 STX1A CLIC1 0.916 22 MMP7 GHR STX1A CRP CLIC1 0.916 23 BDNF MMP7 TGFBI STX1A CLIC1 0.916 24 MMP7 GHR TGFBI STX1A CLIC1 0.916 25 MMP7 GHR C9 STX1A CLIC1 0.916 26 BDNF MMP7 GHR TGFBI CLIC1 0.916 27 MMP7 GHR STX1A NME2 CLIC1 0.916 28 KLK3-SERPINA3 HMGB1 MMP7 STX1A CLIC1 0.916 29 MMP7 C9 STX1A YWHAG NME2 0.916 30 BDNF MMP7 LRIG3 STX1A CLIC1 0.916 31 MMP7 C9 STX1A YWHAG CLIC1 0.916 32 BDNF CDH1 MMP7 STX1A CLIC1 0.916 33 BDNF C9 TGFBI CHRDL1 CLIC1 0.915 34 MMP7 C9 LRIG3 YWHAG TPI1 0.915 35 KLK3-SERPINA3 BDNF MMP7 LRIG3 CLIC1 0.915 36 BDNF C9 LRIG3 CHRDL1 CLIC1 0.915 37 KLK3-SERPINA3 BDNF MMP7 CMA1 CLIC1 0.915 38 BDNF LRIG3 CHRDL1 CRP CLIC1 0.915 39 BDNF MMP7 STX1A ITIH4 CLIC1 0.915 40 BDNF MMP7 GHR C9 CLIC1 0.915 41 BDNF MMP7 C9 GPI CLIC1 0.915 42 HMGB1 MMP7 GHR STX1A CLIC1 0.915 43 BDNF MMP7 LRIG3 GPI CLIC1 0.915 44 GHR BMP1 STX1A CRP CLIC1 0.915 45 BDNF MMP7 BMP1 GPI CLIC1 0.915 46 KLK3-SERPINA3 MMP7 STX1A YWHAG CLIC1 0.915 47 KLK3-SERPINA3 CNTN1 BMP1 CHRDL1 CLIC1 0.915 48 BDNF GHR STX1A CRP CLIC1 0.915 49 KLK3-SERPINA3 BDNF TGFBI STX1A CLIC1 0.915 50 KLK3-SERPINA3 BDNF MMP7 PA2G4 CLIC1 0.915 51 CDH1 MMP7 TGFBI STX1A YWHAG 0.915 52 BDNF MMP7 C9 STX1A CLIC1 0.915 53 MMP7 GHR TGFBI CMA1 CLIC1 0.915 54 BDNF MMP7 TGFBI CMA1 CLIC1 0.915 55 CDH1 MMP7 C9 TGFBI YWHAG 0.915 56 MMP7 C9 LRIG3 YWHAG NME2 0.915 57 BDNF MMP7 STX1A NME2 CLIC1 0.915 58 BDNF EGFR TGFBI STX1A CLIC1 0.915 59 KLK3-SERPINA3 MMP7 LRIG3 GPI CLIC1 0.915 60 BDNF MMP7 STX1A GPI CLIC1 0.915 61 MMP7 C9 LRIG3 YWHAG GPI 0.915 62 KLK3-SERPINA3 MMP7 CMA1 TPI1 CLIC1 0.915 63 CDH1 MMP7 C9 STX1A YWHAG 0.915 64 KLK3-SERPINA3 BDNF CNTN1 CHRDL1 CLIC1 0.915 65 KLK3-SERPINA3 BDNF LRIG3 CHRDL1 CLIC1 0.915 66 BDNF MMP7 GHR LRIG3 CLIC1 0.914 67 KLK3-SERPINA3 BDNF MMP7 NME2 CLIC1 0.914 68 BDNF IGFBP2 MMP7 GPI CLIC1 0.914 69 KLK3-SERPINA3 BDNF STX1A CLIC1 PLA2G7 0.914 70 CDH1 MMP7 GHR CMA1 CLIC1 0.914 71 MMP7 C9 LRIG3 GPI CLIC1 0.914 72 MMP7 GHR STX1A PA2G4 CLIC1 0.914 73 KLK3-SERPINA3 MMP7 STX1A PA2G4 CLIC1 0.914 74 KLK3-SERPINA3 MMP7 STX1A TPI1 CLIC1 0.914 75 KLK3-SERPINA3 MMP7 STX1A HNRNPAB CLIC1 0.914 76 MMP7 GHR LRIG3 GPI CLIC1 0.914 77 MMP7 GHR CMA1 GPI CLIC1 0.914 78 BDNF IGFBP2 MMP7 LRIG3 CLIC1 0.914 79 KLK3-SERPINA3 BDNF MMP7 TPI1 CLIC1 0.914 80 BDNF MMP7 STX1A TPT1 CLIC1 0.914 81 BDNF LRIG3 STX1A CRP CLIC1 0.914 82 BDNF MMP7 STX1A CLIC1 PLA2G7 0.914 83 KLK3-SERPINA3 BDNF AHSG STX1A CLIC1 0.914 84 KLK3-SERPINA3 MMP7 CNTN1 STX1A CLIC1 0.914 85 BDNF GHR TGFBI STX1A CLIC1 0.914 86 BDNF MMP7 NME2 ITIH4 CLIC1 0.914 87 KLK3-SERPINA3 CNTN1 BMP1 STX1A CLIC1 0.914 88 MMP7 C9 CMA1 NME2 CLIC1 0.914 89 BDNF MMP7 LRIG3 NME2 CLIC1 0.914 90 BDNF TGFBI LRIG3 STX1A CLIC1 0.914 91 KLK3-SERPINA3 CDH1 MMP7 STX1A YWHAG 0.914 92 MMP7 C9 LRIG3 YWHAG CLIC1 0.914 93 BDNF MMP7 TGFBI LRIG3 CLIC1 0.914 94 KLK3-SERPINA3 BDNF STX1A CRP CLIC1 0.914 95 BDNF MMP7 BMP1 YWHAG CLIC1 0.914 96 KLK3-SERPINA3 MMP7 LRIG3 CMA1 CLIC1 0.914 97 KLK3-SERPINA3 MMP7 BMP1 STX1A CLIC1 0.914 98 BDNF IGFBP2 MMP7 STX1A CLIC1 0.914 99 KLK3-SERPINA3 MMP7 STX1A YWHAG GPI 0.914 100 MMP7 LRIG3 STX1A YWHAG CLIC1 0.914

TABLE 7 Panels of 6 Biomarkers Markers CV AUC 1 BDNF MMP7 GHR STX1A GPI 0.928 CLIC1 2 BDNF TGFBI LRIG3 CHRDL1 CRP 0.928 CLIC1 3 KLK3-SERPINA3 BDNF MMP7 STX1A NME2 0.928 CLIC1 4 KLK3-SERPINA3 BDNF MMP7 GHR STX1A 0.927 CLIC1 5 BDNF MMP7 GHR TGFBI STX1A 0.927 CLIC1 6 TGFBI LRIG3 CHRDL1 AHSG NME2 0.927 CRP 7 KLK3-SERPINA3 BDNF MMP7 TGFBI STX1A 0.927 CLIC1 8 BDNF MMP7 C9 STX1A YWHAG 0.926 CLIC1 9 KLK3-SERPINA3 BDNF MMP7 STX1A TPT1 0.926 CLIC1 10 BDNF MMP7 GHR STX1A PA2G4 0.926 CLIC1 11 KLK3-SERPINA3 BDNF MMP7 LRIG3 STX1A 0.925 CLIC1 12 BDNF MMP7 C9 LRIG3 YWHAG 0.925 CLIC1 13 KLK3-SERPINA3 MMP7 GHR STX1A TPI1 0.925 CLIC1 14 KLK3-SERPINA3 BDNF KIT MMP7 STX1A 0.925 CLIC1 15 KLK3-SERPINA3 BDNF MMP7 STX1A PA2G4 0.925 CLIC1 16 BDNF MMP7 GHR STX1A NME2 0.925 CLIC1 17 BDNF IGFBP2 MMP7 LRIG3 NME2 0.925 CLIC1 18 BDNF GHR C9 AHSG STX1A 0.925 CLIC1 19 KLK3-SERPINA3 BDNF MMP7 STX1A TPI1 0.925 CLIC1 20 BDNF MMP7 GHR C9 STX1A 0.925 CLIC1 21 BDNF MMP7 GHR STX1A CRP 0.925 CLIC1 22 BDNF MMP7 GHR LRIG3 GPI 0.925 CLIC1 23 KLK3-SERPINA3 BDNF CDH1 MMP7 STX1A 0.925 CLIC1 24 MMP7 GHR C9 STX1A YWHAG 0.925 CLIC1 25 MMP7 GHR C9 STX1A HNRNPAB 0.925 CLIC1 26 KLK3-SERPINA3 BDNF TGFBI CHRDL1 STX1A 0.925 CLIC1 27 KLK3-SERPINA3 BDNF MMP7 STX1A CLIC1 0.925 PLA2G7 28 MMP7 GHR C9 STX1A GPI 0.925 CLIC1 29 BDNF MMP7 GHR LRIG3 YWHAG 0.925 CLIC1 30 KLK3-SERPINA3 MMP7 GHR STX1A NME2 0.925 CLIC1 31 BDNF MMP7 GHR STX1A CLIC1 0.925 PLA2G7 32 BDNF MMP7 GHR STX1A TPT1 0.925 CLIC1 33 BDNF MMP7 C9 STX1A NME2 0.924 CLIC1 34 KLK3-SERPINA3 BDNF MMP7 LRIG3 NME2 0.924 CLIC1 35 BDNF MMP7 LRIG3 STX1A GPI 0.924 CLIC1 36 BDNF MMP7 GHR AHSG STX1A 0.924 CLIC1 37 BDNF MMP7 GHR C9 YWHAG 0.924 CLIC1 38 CDH1 MMP7 GHR STX1A CRP 0.924 CLIC1 39 BDNF IGFBP2 MMP7 LRIG3 GPI 0.924 CLIC1 40 KLK3-SERPINA3 BDNF MMP7 STX1A YWHAG 0.924 CLIC1 41 KLK3-SERPINA3 BDNF MMP7 STX1A GPI 0.924 CLIC1 42 BDNF CDH1 MMP7 GHR STX1A 0.924 CLIC1 43 BDNF IGFBP2 MMP7 TPI1 ITIH4 0.924 CLIC1 44 BDNF MMP7 STX1A NME2 ITIH4 0.924 CLIC1 45 BDNF MMP7 GHR STX1A YWHAG 0.924 CLIC1 46 KLK3-SERPINA3 BDNF CNTN1 TGFBI CHRDL1 0.924 CLIC1 47 KLK3-SERPINA3 CDH1 MMP7 LRIG3 STX1A 0.924 CLIC1 48 KLK3-SERPINA3 MMP7 LRIG3 STX1A NME2 0.924 CLIC1 49 KLK3-SERPINA3 BDNF TGFBI LRIG3 STX1A 0.923 CLIC1 50 BDNF MMP7 TGFBI LRIG3 GPI 0.923 CLIC1 51 BDNF TGFBI LRIG3 STX1A CRP 0.923 CLIC1 52 KLK3-SERPINA3 CDH1 MMP7 GHR STX1A 0.923 CLIC1 53 BDNF MMP7 GHR TGFBI GPI 0.923 CLIC1 54 BDNF MMP7 C9 CMA1 NME2 0.923 CLIC1 55 KLK3-SERPINA3 BDNF MMP7 AHSG STX1A 0.923 CLIC1 56 KLK3-SERPINA3 MMP7 GHR STX1A GPI 0.923 CLIC1 57 BDNF MMP7 C9 STX1A TPT1 0.923 CLIC1 58 BDNF MMP7 GHR CNTN1 TGFBI 0.923 CLIC1 59 MMP7 GHR TGFBI STX1A CRP 0.923 CLIC1 60 KLK3-SERPINA3 MMP7 GHR STX1A YWHAG 0.923 CLIC1 61 TGFBI LRIG3 CHRDL1 STX1A NME2 0.923 CRP 62 BDNF MMP7 C9 STX1A GPI 0.923 CLIC1 63 BDNF IGFBP2 MMP7 TGFBI STX1A 0.923 CLIC1 64 KLK3-SERPINA3 BDNF MMP7 STX1A HNRNPAB 0.923 CLIC1 65 MMP7 GHR C9 STX1A NME2 0.923 CLIC1 66 CDH1 MMP7 GHR TGFBI STX1A 0.923 CLIC1 67 KLK3-SERPINA3 MMP7 GHR STX1A PA2G4 0.923 CLIC1 68 BDNF MMP7 TGFBI STX1A GPI 0.923 CLIC1 69 BDNF MMP7 STX1A YWHAG ITIH4 0.923 CLIC1 70 BDNF MMP7 GHR LRIG3 STX1A 0.923 CLIC1 71 BDNF KIT MMP7 GHR STX1A 0.923 CLIC1 72 MMP7 GHR TGFBI STX1A GPI 0.923 CLIC1 73 BDNF MMP7 STX1A TPI1 ITIH4 0.923 CLIC1 74 BDNF MMP7 TGFBI LRIG3 STX1A 0.923 CLIC1 75 BDNF EGFR TGFBI AHSG STX1A 0.923 CLIC1 76 KLK3-SERPINA3 BDNF TGFBI LRIG3 CHRDL1 0.923 CLIC1 77 CDH1 MMP7 GHR STX1A GPI 0.923 CLIC1 78 BDNF IGFBP2 MMP7 LRIG3 TPI1 0.923 CLIC1 79 BDNF GHR LRIG3 STX1A CRP 0.923 CLIC1 80 BDNF CDH1 MMP7 LRIG3 STX1A 0.923 CLIC1 81 KLK3-SERPINA3 MMP7 GHR TGFBI STX1A 0.923 CLIC1 82 BDNF IGFBP2 LRIG3 AHSG CRP 0.923 CLIC1 83 KLK3-SERPINA3 BDNF MMP7 LRIG3 GPI 0.923 CLIC1 84 BDNF MMP7 GHR LRIG3 NME2 0.923 CLIC1 85 KLK3-SERPINA3 BDNF EGFR TGFBI STX1A 0.923 CLIC1 86 BDNF MMP7 GHR TGFBI LRIG3 0.923 CLIC1 87 MMP7 GHR C9 CMA1 NME2 0.923 CLIC1 88 BDNF MMP7 GHR TGFBI CMA1 0.923 CLIC1 89 MMP7 GHR STX1A NME2 CRP 0.922 CLIC1 90 BDNF MMP7 C9 LRIG3 GPI 0.922 CLIC1 91 KLK3-SERPINA3 BDNF MMP7 LRIG3 TPT1 0.922 CLIC1 92 BDNF MMP7 STX1A TPT1 ITIH4 0.922 CLIC1 93 KIT MMP7 C9 LRIG3 YWHAG 0.922 TPI1 94 BDNF CDH1 MMP7 STX1A ITIH4 0.922 CLIC1 95 MMP7 GHR STX1A TPI1 CRP 0.922 CLIC1 96 BDNF C9 TGFBI LRIG3 CHRDL1 0.922 CLIC1 97 KLK3-SERPINA3 BDNF CNTN1 BMP1 CHRDL1 0.922 CLIC1 98 BDNF GHR TGFBI STX1A CRP 0.922 CLIC1 99 KLK3-SERPINA3 LRIG3 CHRDL1 STX1A CRP 0.922 CLIC1 100 MMP7 GHR LRIG3 STX1A YWHAG 0.922 CLIC1

TABLE 8 Panels of 7 Biomarkers Markers CV AUC 1 BDNF MMP7 GHR TGFBI STX1A 0.933 GPI CLIC1 2 KLK3-SERPINA3 BDNF MMP7 GHR STX1A 0.932 NME2 CLIC1 3 BDNF MMP7 GHR C9 STX1A 0.932 GPI CLIC1 4 KLK3-SERPINA3 BDNF MMP7 GHR STX1A 0.932 PA2G4 CLIC1 5 BDNF MMP7 GHR TGFBI STX1A 0.932 CRP CLIC1 6 BDNF MMP7 GHR TGFBI STX1A 0.932 PA2G4 CLIC1 7 KLK3-SERPINA3 BDNF MMP7 GHR STX1A 0.932 TPI1 CLIC1 8 BDNF MMP7 GHR C9 STX1A 0.932 TPT1 CLIC1 9 KLK3-SERPINA3 BDNF MMP7 STX1A NME2 0.932 ITIH4 CLIC1 10 BDNF CDH1 MMP7 GHR TGFBI 0.932 STX1A CLIC1 11 BDNF TGFBI LRIG3 CHRDL1 STX1A 0.932 CRP CLIC1 12 BDNF MMP7 GHR TGFBI STX1A 0.932 NME2 CLIC1 13 KLK3-SERPINA3 BDNF MMP7 LRIG3 STX1A 0.932 NME2 CLIC1 14 KLK3-SERPINA3 BDNF MMP7 LRIG3 STX1A 0.932 GPI CLIC1 15 KLK3-SERPINA3 BDNF KIT MMP7 GHR 0.931 STX1A CLIC1 16 KLK3-SERPINA3 BDNF CNTN1 TGFBI LRIG3 0.931 CHRDL1 CLIC1 17 BDNF MMP7 GHR C9 STX1A 0.931 NME2 CLIC1 18 KLK3-SERPINA3 BDNF MMP7 LRIG3 STX1A 0.931 TPT1 CLIC1 19 KLK3-SERPINA3 BDNF MMP7 TGFBI LRIG3 0.931 STX1A CLIC1 20 KLK3-SERPINA3 BDNF MMP7 GHR STX1A 0.931 GPI CLIC1 21 BDNF MMP7 GHR C9 STX1A 0.931 YWHAG CLIC1 22 BDNF MMP7 GHR STX1A NME2 0.931 ITIH4 CLIC1 23 BDNF MMP7 GHR TGFBI LRIG3 0.931 STX1A CLIC1 24 KLK3-SERPINA3 BDNF MMP7 GHR STX1A 0.931 TPT1 CLIC1 25 BDNF MMP7 GHR AHSG STX1A 0.931 GPI CLIC1 26 KLK3-SERPINA3 BDNF MMP7 STX1A TPI1 0.931 ITIH4 CLIC1 27 BDNF MMP7 GHR STX1A PA2G4 0.931 GPI CLIC1 28 KLK3-SERPINA3 BDNF KIT MMP7 STX1A 0.931 PA2G4 CLIC1 29 BDNF MMP7 GHR STX1A NME2 0.931 CRP CLIC1 30 KLK3-SERPINA3 BDNF MMP7 TGFBI STX1A 0.931 NME2 CLIC1 31 BDNF MMP7 GHR TGFBI AHSG 0.931 STX1A CLIC1 32 BDNF CDH1 MMP7 GHR AHSG 0.931 STX1A CLIC1 33 KLK3-SERPINA3 BDNF EGFR MMP7 STX1A 0.931 NME2 CLIC1 34 KLK3-SERPINA3 BDNF KIT MMP7 LRIG3 0.931 STX1A CLIC1 35 BDNF MMP7 GHR LRIG3 STX1A 0.930 GPI CLIC1 36 BDNF GHR TGFBI LRIG3 CHRDL1 0.930 CRP CLIC1 37 BDNF MMP7 GHR TGFBI STX1A 0.930 CLIC1 PLA2G7 38 BDNF MMP7 GHR C9 LRIG3 0.930 YWHAG CLIC1 39 BDNF KIT MMP7 GHR STX1A 0.930 TPT1 CLIC1 40 BDNF MMP7 C9 STX1A NME2 0.930 ITIH4 CLIC1 41 KLK3-SERPINA3 BDNF TGFBI LRIG3 CHRDL1 0.930 STX1A CLIC1 42 KLK3-SERPINA3 BDNF KIT MMP7 STX1A 0.930 TPI1 CLIC1 43 BDNF MMP7 TGFBI LRIG3 STX1A 0.930 GPI CLIC1 44 BDNF MMP7 GHR STX1A GPI 0.930 CRP CLIC1 45 BDNF MMP7 GHR TGFBI LRIG3 0.930 GPI CLIC1 46 BDNF MMP7 GHR C9 STX1A 0.930 PA2G4 CLIC1 47 BDNF MMP7 GHR CHRDL1 STX1A 0.930 TPT1 CLIC1 48 KLK3-SERPINA3 BDNF MMP7 CHRDL1 STX1A 0.930 PA2G4 CLIC1 49 BDNF MMP7 GHR AHSG STX1A 0.930 PA2G4 CLIC1 50 KLK3-SERPINA3 BDNF IGFBP2 MMP7 STX1A 0.930 NME2 CLIC1 51 KLK3-SERPINA3 BDNF KIT CDH1 MMP7 0.930 STX1A CLIC1 52 KLK3-SERPINA3 BDNF CDH1 MMP7 LRIG3 0.930 STX1A CLIC1 53 BDNF GHR TGFBI LRIG3 STX1A 0.930 CRP CLIC1 54 KLK3-SERPINA3 BDNF MMP7 TGFBI STX1A 0.930 PA2G4 CLIC1 55 KLK3-SERPINA3 BDNF KIT MMP7 LRIG3 0.930 NME2 CLIC1 56 KLK3-SERPINA3 BDNF MMP7 GHR TGFBI 0.930 STX1A CLIC1 57 KLK3-SERPINA3 BDNF KIT MMP7 STX1A 0.930 NME2 CLIC1 58 BDNF MMP7 GHR SERPINA1 STX1A 0.930 TPI1 CLIC1 59 BDNF EGFR MMP7 GHR TGFBI 0.930 STX1A CLIC1 60 BDNF GHR TGFBI CHRDL1 STX1A 0.930 CRP CLIC1 61 BDNF MMP7 GHR STX1A CRP 0.930 CLIC1 PLA2G7 62 BDNF MMP7 GHR STX1A TPT1 0.930 CRP CLIC1 63 BDNF KIT MMP7 GHR TGFBI 0.930 STX1A CLIC1 64 BDNF KIT MMP7 GHR STX1A 0.930 PA2G4 CLIC1 65 KLK3-SERPINA3 BDNF MMP7 GHR STX1A 0.930 CLIC1 PLA2G7 66 KLK3-SERPINA3 BDNF IGFBP2 MMP7 LRIG3 0.930 NME2 CLIC1 67 BDNF KIT TGFBI LRIG3 CHRDL1 0.930 NME2 CRP 68 TGFBI LRIG3 CHRDL1 AHSG STX1A 0.930 NME2 CRP 69 BDNF MMP7 GHR TGFBI STX1A 0.929 TPI1 CLIC1 70 KLK3-SERPINA3 BDNF MMP7 STX1A NME2 0.929 CLIC1 PLA2G7 71 KLK3-SERPINA3 KIT MMP7 GHR STX1A 0.929 PA2G4 CLIC1 72 KLK3-SERPINA3 BDNF KIT MMP7 LRIG3 0.929 TPI1 CLIC1 73 BDNF CDH1 MMP7 GHR STX1A 0.929 GPI CLIC1 74 BDNF MMP7 GHR TGFBI STX1A 0.929 TPT1 CLIC1 75 BDNF MMP7 GHR LRIG3 GPI 0.929 CRP CLIC1 76 KLK3-SERPINA3 BDNF MMP7 C9 STX1A 0.929 NME2 CLIC1 77 BDNF MMP7 C9 TGFBI CMA1 0.929 NME2 CLIC1 78 CDH1 MMP7 GHR TGFBI STX1A 0.929 CRP CLIC1 79 BDNF MMP7 GHR C9 STX1A 0.929 HNRNPAB CLIC1 80 BDNF MMP7 C9 LRIG3 STX1A 0.929 YWHAG CLIC1 81 BDNF IGFBP2 TGFBI LRIG3 STX1A 0.929 CRP CLIC1 82 BDNF MMP7 GHR LRIG3 STX1A 0.929 NME2 CLIC1 83 BDNF IGFBP2 MMP7 LRIG3 NME2 0.929 CRP CLIC1 84 BDNF MMP7 GHR CHRDL1 STX1A 0.929 PA2G4 CLIC1 85 BDNF MMP7 GHR C9 TGFBI 0.929 STX1A CLIC1 86 BDNF MMP7 C9 TGFBI STX1A 0.929 NME2 CLIC1 87 BDNF EGFR MMP7 STX1A TPI1 0.929 ITIH4 CLIC1 88 KLK3-SERPINA3 BDNF MMP7 C9 STX1A 0.929 YWHAG CLIC1 89 KLK3-SERPINA3 BDNF MMP7 LRIG3 STX1A 0.929 PA2G4 CLIC1 90 KLK3-SERPINA3 BDNF MMP7 STX1A PA2G4 0.929 ITIH4 CLIC1 91 KLK3-SERPINA3 BDNF MMP7 LRIG3 STX1A 0.929 HNRNPAB CLIC1 92 KLK3-SERPINA3 BDNF EGFR MMP7 TGFBI 0.929 STX1A CLIC1 93 BDNF MMP7 GHR STX1A TPI1 0.929 ITIH4 CLIC1 94 BDNF CDH1 MMP7 GHR STX1A 0.929 CRP CLIC1 95 BDNF MMP7 GHR STX1A NME2 0.929 CLIC1 PLA2G7 96 KLK3-SERPINA3 BDNF MMP7 TGFBI STX1A 0.929 TPI1 CLIC1 97 BDNF MMP7 GHR STX1A PA2G4 0.929 ITIH4 CLIC1 98 MMP7 GHR BMP1 STX1A NME2 0.929 CRP CLIC1 99 KLK3-SERPINA3 BDNF MMP7 STX1A L1CAM 0.929 CLIC1 PLA2G7 100 BDNF KIT MMP7 GHR STX1A 0.929 GPI CLIC1

TABLE 9 Panels of 8 Biomarkers Markers CV AUC 1 KLK3-SERPINA3 BDNF KIT MMP7 GHR 0.940 STX1A PA2G4 CLIC1 2 BDNF TGFBI LRIG3 CHRDL1 AHSG 0.938 STX1A CRP CLIC1 3 BDNF MMP7 GHR TGFBI STX1A 0.938 NME2 CRP CLIC1 4 KLK3-SERPINA3 BDNF KIT MMP7 LRIG3 0.937 STX1A NME2 CLIC1 5 BDNF MMP7 GHR TGFBI LRIG3 0.937 STX1A NME2 CLIC1 6 KLK3-SERPINA3 BDNF MMP7 GHR TGFBI 0.937 STX1A NME2 CLIC1 7 KLK3-SERPINA3 BDNF KIT MMP7 GHR 0.937 STX1A TPT1 CLIC1 8 KLK3-SERPINA3 BDNF MMP7 GHR LRIG3 0.937 STX1A NME2 CLIC1 9 BDNF MMP7 GHR TGFBI LRIG3 0.937 STX1A GPI CLIC1 10 BDNF MMP7 GHR TGFBI STX1A 0.936 GPI CRP CLIC1 11 KLK3-SERPINA3 BDNF KIT MMP7 GHR 0.936 STX1A TPI1 CLIC1 12 BDNF EGFR MMP7 GHR TGFBI 0.936 STX1A NME2 CLIC1 13 BDNF MMP7 GHR C9 STX1A 0.936 PA2G4 GPI CLIC1 14 KLK3-SERPINA3 BDNF MMP7 GHR TGFBI 0.936 STX1A PA2G4 CLIC1 15 KLK3-SERPINA3 BDNF MMP7 TGFBI LRIG3 0.936 STX1A NME2 CLIC1 16 BDNF CDH1 MMP7 GHR TGFBI 0.936 AHSG STX1A CLIC1 17 KLK3-SERPINA3 BDNF MMP7 GHR AHSG 0.936 STX1A PA2G4 CLIC1 18 BDNF EGFR MMP7 GHR TGFBI 0.936 STX1A GPI CLIC1 19 KLK3-SERPINA3 BDNF KIT MMP7 GHR 0.936 STX1A NME2 CLIC1 20 KLK3-SERPINA3 BDNF MMP7 GHR STX1A 0.936 PA2G4 GPI CLIC1 21 BDNF GHR TGFBI LRIG3 AHSG 0.936 STX1A CRP CLIC1 22 BDNF MMP7 GHR TGFBI STX1A 0.936 TPI1 CRP CLIC1 23 BDNF KIT MMP7 GHR LRIG3 0.936 STX1A NME2 CLIC1 24 BDNF KIT MMP7 GHR C9 0.936 STX1A PA2G4 CLIC1 25 KLK3-SERPINA3 BDNF CDH1 MMP7 LRIG3 0.936 STX1A TPT1 CLIC1 26 KLK3-SERPINA3 BDNF KIT MMP7 STX1A 0.936 TPI1 ITIH4 CLIC1 27 KLK3-SERPINA3 BDNF MMP7 GHR TGFBI 0.935 STX1A GPI CLIC1 28 BDNF KIT MMP7 GHR C9 0.935 STX1A TPT1 CLIC1 29 KLK3-SERPINA3 BDNF MMP7 TGFBI LRIG3 0.935 STX1A GPI CLIC1 30 KLK3-SERPINA3 BDNF KIT MMP7 STX1A 0.935 NME2 ITIH4 CLIC1 31 BDNF MMP7 GHR TGFBI AHSG 0.935 STX1A GPI CLIC1 32 BDNF KIT MMP7 GHR STX1A 0.935 PA2G4 ITIH4 CLIC1 33 KLK3-SERPINA3 BDNF MMP7 LRIG3 CHRDL1 0.935 STX1A NME2 CLIC1 34 BDNF MMP7 GHR TGFBI STX1A 0.935 PA2G4 CRP CLIC1 35 BDNF MMP7 GHR TGFBI LRIG3 0.935 STX1A CRP CLIC1 36 BDNF MMP7 GHR TGFBI LRIG3 0.935 GPI CRP CLIC1 37 KLK3-SERPINA3 BDNF MMP7 LRIG3 CHRDL1 0.935 STX1A TPI1 CLIC1 38 KLK3-SERPINA3 BDNF KIT CDH1 MMP7 0.935 LRIG3 STX1A CLIC1 39 KLK3-SERPINA3 BDNF MMP7 LRIG3 CHRDL1 0.935 STX1A TPT1 CLIC1 40 BDNF GHR TGFBI CHRDL1 AHSG 0.935 STX1A CRP CLIC1 41 KLK3-SERPINA3 BDNF KIT MMP7 LRIG3 0.935 STX1A TPT1 CLIC1 42 KLK3-SERPINA3 BDNF MMP7 GHR TGFBI 0.935 STX1A TPI1 CLIC1 43 KLK3-SERPINA3 BDNF MMP7 GHR CHRDL1 0.935 STX1A PA2G4 CLIC1 44 BDNF MMP7 GHR TGFBI CHRDL1 0.935 STX1A PA2G4 CLIC1 45 KLK3-SERPINA3 BDNF MMP7 GHR CHRDL1 0.935 STX1A TPT1 CLIC1 46 BDNF MMP7 GHR C9 TGFBI 0.935 STX1A TPT1 CLIC1 47 KLK3-SERPINA3 BDNF KIT MMP7 GHR 0.935 TGFBI STX1A CLIC1 48 KLK3-SERPINA3 BDNF KIT MMP7 LRIG3 0.935 STX1A TPI1 CLIC1 49 BDNF MMP7 GHR STX1A TPI1 0.935 CRP ITIH4 CLIC1 50 KLK3-SERPINA3 BDNF KIT MMP7 STX1A 0.935 PA2G4 ITIH4 CLIC1 51 BDNF CDH1 MMP7 GHR TGFBI 0.935 STX1A CRP CLIC1 52 BDNF MMP7 GHR C9 TGFBI 0.935 STX1A NME2 CLIC1 53 BDNF KIT MMP7 GHR C9 0.935 STX1A GPI CLIC1 54 KLK3-SERPINA3 BDNF MMP7 GHR LRIG3 0.935 STX1A TPT1 CLIC1 55 BDNF KIT MMP7 GHR TGFBI 0.935 STX1A PA2G4 CLIC1 56 BDNF MMP7 GHR C9 AHSG 0.935 STX1A NME2 CLIC1 57 KLK3-SERPINA3 BDNF MMP7 GHR LRIG3 0.935 STX1A GPI CLIC1 58 BDNF MMP7 GHR STX1A NME2 0.935 GPI CRP CLIC1 59 BDNF GHR TGFBI LRIG3 CHRDL1 0.935 AHSG CRP CLIC1 60 KLK3-SERPINA3 BDNF MMP7 GHR STX1A 0.935 NME2 CLIC1 PLA2G7 61 BDNF KIT MMP7 GHR STX1A 0.935 TPI1 ITIH4 CLIC1 62 BDNF MMP7 GHR C9 STX1A 0.935 NME2 CLIC1 PLA2G7 63 BDNF MMP7 GHR C9 STX1A 0.935 NME2 ITIH4 CLIC1 64 BDNF MMP7 GHR LRIG3 STX1A 0.935 NME2 CRP CLIC1 65 BDNF MMP7 GHR C9 TGFBI 0.935 STX1A YWHAG CLIC1 66 BDNF MMP7 GHR CHRDL1 STX1A 0.935 PA2G4 CRP CLIC1 67 BDNF MMP7 GHR TGFBI LRIG3 0.935 STX1A PA2G4 CLIC1 68 BDNF MMP7 GHR C9 STX1A 0.935 TPI1 ITIH4 CLIC1 69 BDNF EGFR MMP7 GHR TGFBI 0.935 AHSG STX1A CLIC1 70 BDNF MMP7 GHR CHRDL1 STX1A 0.935 TPT1 CRP CLIC1 71 BDNF MMP7 GHR STX1A NME2 0.935 CRP ITIH4 CLIC1 72 KLK3-SERPINA3 BDNF MMP7 GHR TGFBI 0.935 LRIG3 STX1A CLIC1 73 KLK3-SERPINA3 BDNF MMP7 TGFBI LRIG3 0.935 STX1A TPI1 CLIC1 74 BDNF MMP7 GHR TGFBI STX1A 0.935 CRP CLIC1 PLA2G7 75 KLK3-SERPINA3 BDNF MMP7 TGFBI CHRDL1 0.935 STX1A PA2G4 CLIC1 76 BDNF MMP7 GHR TGFBI STX1A 0.934 PA2G4 GPI CLIC1 77 BDNF MMP7 GHR C9 TGFBI 0.934 STX1A GPI CLIC1 78 BDNF GHR TGFBI LRIG3 CHRDL1 0.934 STX1A CRP CLIC1 79 BDNF MMP7 GHR TGFBI STX1A 0.934 TPI1 ITIH4 CLIC1 80 KLK3-SERPINA3 BDNF TGFBI LRIG3 CHRDL1 0.934 STX1A CRP CLIC1 81 BDNF MMP7 GHR C9 CHRDL1 0.934 STX1A TPT1 CLIC1 82 KLK3-SERPINA3 BDNF KIT MMP7 GHR 0.934 STX1A HNRNPAB CLIC1 83 BDNF MMP7 GHR CHRDL1 STX1A 0.934 NME2 CRP CLIC1 84 KLK3-SERPINA3 BDNF EGFR MMP7 TGFBI 0.934 STX1A NME2 CLIC1 85 BDNF KIT MMP7 GHR C9 0.934 STX1A HNRNPAB CLIC1 86 BDNF MMP7 GHR C9 STX1A 0.934 NME2 GPI CLIC1 87 BDNF KIT MMP7 GHR TGFBI 0.934 LRIG3 STX1A CLIC1 88 BDNF MMP7 GHR TGFBI AHSG 0.934 STX1A CLIC1 PLA2G7 89 KLK3-SERPINA3 BDNF KIT MMP7 LRIG3 0.934 STX1A HNRNPAB CLIC1 90 BDNF KIT MMP7 GHR TGFBI 0.934 STX1A NME2 CLIC1 91 BDNF MMP7 GHR STX1A NME2 0.934 CRP CLIC1 PLA2G7 92 KLK3-SERPINA3 BDNF MMP7 GHR AHSG 0.934 STX1A NME2 CLIC1 93 KLK3-SERPINA3 BDNF MMP7 GHR AHSG 0.934 STX1A TPI1 CLIC1 94 BDNF MMP7 GHR TGFBI STX1A 0.934 CRP HNRNPAB CLIC1 95 BDNF MMP7 GHR CHRDL1 STX1A 0.934 PA2G4 GPI CLIC1 96 KLK3-SERPINA3 BDNF KIT MMP7 LRIG3 0.934 STX1A PA2G4 CLIC1 97 BDNF MMP7 GHR CHRDL1 AHSG 0.934 STX1A PA2G4 CLIC1 98 BDNF MMP7 GHR TGFBI STX1A 0.934 GPI CLIC1 PLA2G7 99 KLK3-SERPINA3 BDNF MMP7 GHR C9 0.934 STX1A TPT1 CLIC1 100 BDNF MMP7 GHR C9 STX1A 0.934 TPT1 ITIH4 CLIC1

TABLE 10 Panels of 9 Biomarkers Markers CV AUC 1 BDNF MMP7 GHR TGFBI LRIG3 0.941 STX1A NME2 CRP CLIC1 2 BDNF MMP7 GHR TGFBI CHRDL1 0.941 STX1A PA2G4 CRP CLIC1 3 KLK3-SERPINA3 BDNF KIT MMP7 GHR 0.941 TGFBI STX1A TPI1 CLIC1 4 BDNF KIT MMP7 GHR LRIG3 0.941 STX1A NME2 CRP CLIC1 5 KLK3-SERPINA3 BDNF KIT MMP7 GHR 0.941 TGFBI STX1A PA2G4 CLIC1 6 BDNF MMP7 GHR TGFBI CHRDL1 0.941 STX1A TPI1 CRP CLIC1 7 KLK3-SERPINA3 BDNF MMP7 TGFBI LRIG3 0.940 CHRDL1 STX1A NME2 CLIC1 8 BDNF MMP7 GHR TGFBI LRIG3 0.940 STX1A GPI CRP CLIC1 9 KLK3-SERPINA3 BDNF MMP7 GHR TGFBI 0.940 CHRDL1 STX1A TPI1 CLIC1 10 KLK3-SERPINA3 BDNF KIT MMP7 GHR 0.940 LRIG3 STX1A NME2 CLIC1 11 KLK3-SERPINA3 BDNF KIT MMP7 GHR 0.940 LRIG3 STX1A TPI1 CLIC1 12 KLK3-SERPINA3 BDNF MMP7 GHR TGFBI 0.940 LRIG3 STX1A GPI CLIC1 13 KLK3-SERPINA3 BDNF KIT MMP7 GHR 0.940 STX1A PA2G4 GPI CLIC1 14 BDNF EGFR MMP7 GHR TGFBI 0.940 AHSG STX1A NME2 CLIC1 15 BDNF EGFR MMP7 GHR TGFBI 0.940 STX1A NME2 CRP CLIC1 16 BDNF MMP7 GHR TGFBI CHRDL1 0.940 STX1A NME2 CRP CLIC1 17 BDNF KIT MMP7 GHR C9 0.940 STX1A PA2G4 GPI CLIC1 18 KLK3-SERPINA3 BDNF KIT MMP7 GHR 0.940 LRIG3 STX1A PA2G4 CLIC1 19 KLK3-SERPINA3 BDNF MMP7 GHR TGFBI 0.940 LRIG3 STX1A NME2 CLIC1 20 BDNF MMP7 GHR TGFBI AHSG 0.940 STX1A GPI CRP CLIC1 21 BDNF MMP7 GHR TGFBI CHRDL1 0.940 STX1A TPT1 CRP CLIC1 22 KLK3-SERPINA3 BDNF KIT MMP7 GHR 0.940 LRIG3 STX1A TPT1 CLIC1 23 BDNF CDH1 MMP7 GHR TGFBI 0.940 STX1A NME2 CRP CLIC1 24 BDNF MMP7 GHR TGFBI CHRDL1 0.940 AHSG STX1A PA2G4 CLIC1 25 BDNF MMP7 GHR TGFBI STX1A 0.940 NME2 GPI CRP CLIC1 26 BDNF KIT MMP7 GHR STX1A 0.940 TPI1 CRP ITIH4 CLIC1 27 KLK3-SERPINA3 BDNF MMP7 GHR TGFBI 0.939 CHRDL1 STX1A TPT1 CLIC1 28 KLK3-SERPINA3 BDNF KIT MMP7 GHR 0.939 TGFBI LRIG3 STX1A CLIC1 29 BDNF IGFBP2 MMP7 TGFBI LRIG3 0.939 STX1A NME2 CRP CLIC1 30 KLK3-SERPINA3 BDNF KIT MMP7 GHR 0.939 AHSG STX1A PA2G4 CLIC1 31 BDNF MMP7 GHR C9 CHRDL1 0.939 STX1A PA2G4 GPI CLIC1 32 BDNF MMP7 GHR CHRDL1 STX1A 0.939 TPI1 CRP ITIH4 CLIC1 33 KLK3-SERPINA3 BDNF MMP7 TGFBI LRIG3 0.939 CHRDL1 STX1A TPI1 CLIC1 34 KLK3-SERPINA3 BDNF KIT MMP7 GHR 0.939 TGFBI STX1A NME2 CLIC1 35 KLK3-SERPINA3 BDNF MMP7 GHR CHRDL1 0.939 AHSG STX1A TPI1 CLIC1 36 BDNF MMP7 GHR TGFBI STX1A 0.939 PA2G4 CRP ITIH4 CLIC1 37 BDNF KIT MMP7 GHR C9 0.939 STX1A TPI1 ITIH4 CLIC1 38 KLK3-SERPINA3 BDNF MMP7 GHR CHRDL1 0.939 STX1A NME2 PA2G4 CLIC1 39 BDNF KIT MMP7 GHR STX1A 0.939 PA2G4 CRP ITIH4 CLIC1 40 BDNF MMP7 GHR CHRDL1 STX1A 0.939 PA2G4 GPI CRP CLIC1 41 KLK3-SERPINA3 BDNF IGFBP2 MMP7 TGFBI 0.939 LRIG3 STX1A NME2 CLIC1 42 BDNF MMP7 GHR TGFBI STX1A 0.939 NME2 CRP ITIH4 CLIC1 43 KLK3-SERPINA3 BDNF KIT MMP7 GHR 0.939 LRIG3 STX1A HNRNPAB CLIC1 44 BDNF KIT MMP7 GHR TGFBI 0.939 LRIG3 STX1A NME2 CLIC1 45 BDNF MMP7 GHR C9 TGFBI 0.939 STX1A NME2 GPI CLIC1 46 KLK3-SERPINA3 BDNF MMP7 GHR TGFBI 0.939 STX1A NME2 CRP CLIC1 47 KLK3-SERPINA3 BDNF MMP7 GHR TGFBI 0.939 STX1A GPI CRP CLIC1 48 KLK3-SERPINA3 BDNF MMP7 GHR TGFBI 0.939 STX1A TPI1 CRP CLIC1 49 BDNF KIT MMP7 GHR TGFBI 0.939 STX1A TPI1 CRP CLIC1 50 BDNF MMP7 GHR TGFBI CHRDL1 0.939 SERPINA1 STX1A TPI1 CLIC1 51 KLK3-SERPINA3 BDNF KIT MMP7 TGFBI 0.939 LRIG3 STX1A TPI1 CLIC1 52 BDNF KIT MMP7 GHR TGFBI 0.939 STX1A NME2 CRP CLIC1 53 BDNF KIT MMP7 GHR TGFBI 0.939 LRIG3 STX1A CRP CLIC1 54 KLK3-SERPINA3 BDNF KIT MMP7 GHR 0.939 STX1A PA2G4 ITIH4 CLIC1 55 KLK3-SERPINA3 BDNF MMP7 GHR CHRDL1 0.939 STX1A PA2G4 GPI CLIC1 56 BDNF GHR TGFBI LRIG3 CHRDL1 0.939 AHSG STX1A CRP CLIC1 57 KLK3-SERPINA3 BDNF KIT CDH1 MMP7 0.939 GHR STX1A TPT1 CLIC1 58 KLK3-SERPINA3 BDNF EGFR MMP7 GHR 0.939 TGFBI STX1A PA2G4 CLIC1 59 KLK3-SERPINA3 BDNF MMP7 GHR TGFBI 0.939 AHSG STX1A GPI CLIC1 60 KLK3-SERPINA3 BDNF KIT MMP7 TGFBI 0.939 LRIG3 STX1A NME2 CLIC1 61 KLK3-SERPINA3 BDNF MMP7 GHR TGFBI 0.939 CHRDL1 STX1A PA2G4 CLIC1 62 BDNF KIT MMP7 GHR TGFBI 0.939 LRIG3 STX1A TPI1 CLIC1 63 BDNF CDH1 MMP7 GHR TGFBI 0.939 AHSG STX1A CRP CLIC1 64 BDNF MMP7 GHR CHRDL1 AHSG 0.939 STX1A PA2G4 CRP CLIC1 65 BDNF KIT MMP7 GHR TGFBI 0.939 STX1A TPI1 ITIH4 CLIC1 66 KLK3-SERPINA3 BDNF MMP7 GHR TGFBI 0.939 AHSG STX1A PA2G4 CLIC1 67 BDNF EGFR MMP7 GHR TGFBI 0.939 AHSG STX1A CLIC1 PLA2G7 68 KLK3-SERPINA3 BDNF KIT MMP7 GHR 0.938 TGFBI STX1A TPT1 CLIC1 69 KLK3-SERPINA3 BDNF MMP7 CHRDL1 STX1A 0.938 NME2 PA2G4 ITIH4 CLIC1 70 KLK3-SERPINA3 BDNF KIT MMP7 LRIG3 0.938 STX1A TPI1 ITIH4 CLIC1 71 BDNF KIT MMP7 GHR C9 0.938 LRIG3 STX1A NME2 CLIC1 72 BDNF KIT MMP7 GHR TGFBI 0.938 LRIG3 STX1A GPI CLIC1 73 KLK3-SERPINA3 BDNF MMP7 GHR TGFBI 0.938 STX1A NME2 GPI CLIC1 74 KLK3-SERPINA3 BDNF KIT CDH1 MMP7 0.938 GHR STX1A PA2G4 CLIC1 75 KLK3-SERPINA3 BDNF EGFR MMP7 TGFBI 0.938 LRIG3 STX1A NME2 CLIC1 76 KLK3-SERPINA3 BDNF KIT MMP7 GHR 0.938 LRIG3 STX1A GPI CLIC1 77 BDNF KIT MMP7 GHR LRIG3 0.938 STX1A TPI1 CRP CLIC1 78 KLK3-SERPINA3 BDNF MMP7 GHR AHSG 0.938 STX1A PA2G4 GPI CLIC1 79 BDNF KIT MMP7 GHR TGFBI 0.938 STX1A PA2G4 ITIH4 CLIC1 80 KLK3-SERPINA3 BDNF MMP7 GHR CHRDL1 0.938 STX1A TPT1 PA2G4 CLIC1 81 BDNF MMP7 GHR CHRDL1 AHSG 0.938 STX1A TPI1 CRP CLIC1 82 KLK3-SERPINA3 BDNF KIT CDH1 MMP7 0.938 LRIG3 STX1A NME2 CLIC1 83 BDNF KIT MMP7 GHR C9 0.938 STX1A PA2G4 ITIH4 CLIC1 84 BDNF IGFBP2 MMP7 GHR TGFBI 0.938 AHSG STX1A TPI1 CLIC1 85 KLK3-SERPINA3 BDNF KIT MMP7 GHR 0.938 STX1A TPI1 ITIH4 CLIC1 86 BDNF MMP7 GHR CHRDL1 AHSG 0.938 STX1A TPT1 CRP CLIC1 87 BDNF MMP7 GHR TGFBI STX1A 0.938 TPI1 CRP ITIH4 CLIC1 88 BDNF KIT MMP7 GHR STX1A 0.938 NME2 CRP ITIH4 CLIC1 89 KLK3-SERPINA3 BDNF EGFR MMP7 GHR 0.938 AHSG STX1A PA2G4 CLIC1 90 KLK3-SERPINA3 BDNF MMP7 GHR TGFBI 0.938 CHRDL1 STX1A NME2 CLIC1 91 BDNF MMP7 GHR TGFBI LRIG3 0.938 STX1A NME2 GPI CLIC1 92 BDNF CDH1 MMP7 GHR TGFBI 0.938 LRIG3 AHSG STX1A CLIC1 93 BDNF CDH1 MMP7 GHR TGFBI 0.938 STX1A GPI CRP CLIC1 94 KLK3-SERPINA3 BDNF MMP7 GHR STX1A 0.938 NME2 GPI CRP CLIC1 95 BDNF MMP7 GHR C9 CHRDL1 0.938 AHSG STX1A TPI1 CLIC1 96 BDNF KIT MMP7 GHR TGFBI 0.938 STX1A PA2G4 CRP CLIC1 97 KLK3-SERPINA3 BDNF EGFR MMP7 GHR 0.938 TGFBI STX1A TPI1 CLIC1 98 BDNF MMP7 GHR TGFBI STX1A 0.938 NME2 CRP CLIC1 PLA2G7 99 BDNF MMP7 GHR TGFBI BMP1 0.938 STX1A NME2 CRP CLIC1 100 BDNF EGFR MMP7 GHR TGFBI 0.938 STX1A GPI CRP CLIC1

TABLE 11 Panels of 10 Biomarkers Markers CV AUC 1 BDNF MMP7 GHR TGFBI CHRDL1 0.944 SERPINA1 STX1A NME2 PA2G4 CLIC1 2 BDNF MMP7 GHR TGFBI CHRDL1 0.944 AHSG STX1A TPI1 CRP CLIC1 3 BDNF KIT MMP7 GHR TGFBI 0.944 LRIG3 STX1A NME2 CRP CLIC1 4 BDNF MMP7 GHR TGFBI CHRDL1 0.944 STX1A PA2G4 CRP ITIH4 CLIC1 5 BDNF KIT MMP7 GHR TGFBI 0.944 STX1A TPI1 CRP ITIH4 CLIC1 6 BDNF MMP7 GHR TGFBI CHRDL1 0.943 STX1A TPI1 CRP ITIH4 CLIC1 7 KLK3-SERPINA3 BDNF MMP7 GHR TGFBI 0.943 CHRDL1 AHSG STX1A TPI1 CLIC1 8 BDNF MMP7 GHR TGFBI LRIG3 0.943 CHRDL1 STX1A TPI1 CRP CLIC1 9 KLK3-SERPINA3 BDNF MMP7 GHR TGFBI 0.943 CHRDL1 STX1A TPI1 CRP CLIC1 10 KLK3-SERPINA3 BDNF KIT MMP7 GHR 0.943 TGFBI LRIG3 STX1A TPI1 CLIC1 11 BDNF MMP7 GHR TGFBI CHRDL1 0.943 STX1A PA2G4 GPI CRP CLIC1 12 BDNF MMP7 GHR TGFBI CHRDL1 0.943 AHSG STX1A NME2 CRP CLIC1 13 BDNF IGFBP2 MMP7 GHR TGFBI 0.943 LRIG3 STX1A NME2 CRP CLIC1 14 BDNF KIT MMP7 GHR TGFBI 0.943 STX1A PA2G4 CRP ITIH4 CLIC1 15 BDNF KIT MMP7 GHR TGFBI 0.943 LRIG3 STX1A TPI1 CRP CLIC1 16 BDNF MMP7 GHR C9 TGFBI 0.943 CHRDL1 STX1A PA2G4 GPI CLIC1 17 BDNF MMP7 GHR TGFBI CHRDL1 0.943 AHSG STX1A PA2G4 CRP CLIC1 18 BDNF MMP7 GHR TGFBI CHRDL1 0.943 STX1A NME2 PA2G4 CRP CLIC1 19 BDNF EGFR MMP7 GHR TGFBI 0.943 CHRDL1 STX1A TPI1 CRP CLIC1 20 BDNF MMP7 GHR TGFBI CHRDL1 0.943 STX1A NME2 CRP ITIH4 CLIC1 21 BDNF MMP7 GHR CHRDL1 STX1A 0.943 NME2 PA2G4 CRP ITIH4 CLIC1 22 BDNF MMP7 GHR TGFBI LRIG3 0.942 CHRDL1 STX1A NME2 CRP CLIC1 23 KLK3-SERPINA3 BDNF MMP7 GHR CHRDL1 0.942 STX1A NME2 PA2G4 CRP CLIC1 24 KLK3-SERPINA3 BDNF MMP7 TGFBI LRIG3 0.942 CHRDL1 SERPINA1 STX1A TPI1 CLIC1 25 KLK3-SERPINA3 BDNF MMP7 GHR CHRDL1 0.942 AHSG STX1A TPI1 CRP CLIC1 26 BDNF KIT MMP7 GHR TGFBI 0.942 LRIG3 STX1A TPT1 CRP CLIC1 27 BDNF MMP7 GHR TGFBI LRIG3 0.942 AHSG STX1A NME2 CRP CLIC1 28 KLK3-SERPINA3 BDNF MMP7 GHR CHRDL1 0.942 AHSG STX1A PA2G4 GPI CLIC1 29 BDNF MMP7 GHR C9 CHRDL1 0.942 AHSG STX1A TPT1 PA2G4 CLIC1 30 KLK3-SERPINA3 BDNF EGFR MMP7 GHR 0.942 TGFBI AHSG STX1A TPI1 CLIC1 31 KLK3-SERPINA3 BDNF EGFR MMP7 GHR 0.942 TGFBI AHSG STX1A NME2 CLIC1 32 BDNF EGFR MMP7 GHR TGFBI 0.942 AHSG STX1A NME2 ITIH4 CLIC1 33 BDNF MMP7 GHR TGFBI LRIG3 0.942 STX1A NME2 GPI CRP CLIC1 34 BDNF MMP7 GHR C9 TGFBI 0.942 CHRDL1 STX1A NME2 PA2G4 CLIC1 35 KLK3-SERPINA3 BDNF MMP7 GHR TGFBI 0.942 CHRDL1 STX1A PA2G4 CRP CLIC1 36 BDNF MMP7 GHR TGFBI CHRDL1 0.942 AHSG STX1A PA2G4 ITIH4 CLIC1 37 KLK3-SERPINA3 BDNF KIT MMP7 GHR 0.942 LRIG3 AHSG STX1A NME2 CLIC1 38 BDNF KIT EGFR MMP7 GHR 0.942 TGFBI STX1A TPI1 ITIH4 CLIC1 39 KLK3-SERPINA3 BDNF MMP7 GHR TGFBI 0.942 CHRDL1 AHSG STX1A PA2G4 CLIC1 40 KLK3-SERPINA3 BDNF MMP7 GHR TGFBI 0.942 LRIG3 STX1A GPI CRP CLIC1 41 BDNF MMP7 GHR CHRDL1 AHSG 0.942 STX1A PA2G4 GPI CRP CLIC1 42 BDNF KIT MMP7 GHR TGFBI 0.942 LRIG3 STX1A TPI1 ITIH4 CLIC1 43 KLK3-SERPINA3 BDNF KIT MMP7 GHR 0.942 TGFBI AHSG STX1A PA2G4 CLIC1 44 KLK3-SERPINA3 BDNF KIT MMP7 GHR 0.942 TGFBI LRIG3 STX1A PA2G4 CLIC1 45 KLK3-SERPINA3 BDNF MMP7 GHR TGFBI 0.942 CHRDL1 STX1A NME2 PA2G4 CLIC1 46 KLK3-SERPINA3 BDNF KIT MMP7 GHR 0.942 TGFBI LRIG3 STX1A NME2 CLIC1 47 BDNF MMP7 GHR C9 CHRDL1 0.942 AHSG STX1A PA2G4 GPI CLIC1 48 BDNF MMP7 GHR C9 CHRDL1 0.942 AHSG GPI TPI1 CRP CLIC1 49 BDNF CDH1 MMP7 GHR TGFBI 0.942 LRIG3 STX1A NME2 CRP CLIC1 50 BDNF EGFR MMP7 GHR TGFBI 0.942 AHSG STX1A NME2 CRP CLIC1 51 BDNF MMP7 GHR TGFBI CHRDL1 0.942 SERPINA1 STX1A TPI1 CRP CLIC1 52 BDNF CDH1 MMP7 GHR CHRDL1 0.942 AHSG STX1A TPT1 CRP CLIC1 53 BDNF EGFR MMP7 GHR TGFBI 0.942 STX1A TPI1 CRP ITIH4 CLIC1 54 KLK3-SERPINA3 BDNF MMP7 GHR TGFBI 0.942 LRIG3 CHRDL1 STX1A TPI1 CLIC1 55 BDNF MMP7 GHR TGFBI LRIG3 0.942 CHRDL1 STX1A CRP HNRNPAB CLIC1 56 KLK3-SERPINA3 BDNF KIT MMP7 GHR 0.942 TGFBI LRIG3 STX1A TPT1 CLIC1 57 KLK3-SERPINA3 BDNF KIT MMP7 GHR 0.942 LRIG3 STX1A TPI1 ITIH4 CLIC1 58 KLK3-SERPINA3 BDNF KIT MMP7 GHR 0.942 TGFBI STX1A PA2G4 CRP CLIC1 59 BDNF MMP7 GHR TGFBI CHRDL1 0.942 STX1A NME2 CRP CLIC1 PLA2G7 60 BDNF EGFR MMP7 GHR C9 0.942 TGFBI AHSG STX1A NME2 CLIC1 61 BDNF KIT MMP7 GHR TGFBI 0.942 CHRDL1 TPI1 CRP ITIH4 CLIC1 62 BDNF MMP7 GHR TGFBI LRIG3 0.942 CHRDL1 STX1A GPI CRP CLIC1 63 BDNF MMP7 GHR TGFBI LRIG3 0.942 CHRDL1 AHSG STX1A NME2 CLIC1 64 KLK3-SERPINA3 BDNF KIT MMP7 GHR 0.942 TGFBI STX1A PA2G4 ITIH4 CLIC1 65 KLK3-SERPINA3 BDNF KIT EGFR MMP7 0.942 GHR TGFBI STX1A PA2G4 CLIC1 66 KLK3-SERPINA3 BDNF KIT CDH1 MMP7 0.942 GHR LRIG3 STX1A NME2 CLIC1 67 BDNF MMP7 GHR TGFBI CHRDL1 0.942 STX1A PA2G4 GPI ITIH4 CLIC1 68 BDNF MMP7 GHR TGFBI LRIG3 0.942 CHRDL1 GPI TPI1 CRP CLIC1 69 KLK3-SERPINA3 BDNF MMP7 GHR TGFBI 0.942 STX1A GPI TPI1 CRP CLIC1 70 BDNF MMP7 GHR TGFBI CHRDL1 0.942 FN1 STX1A TPI1 CRP CLIC1 71 BDNF EGFR MMP7 GHR TGFBI 0.942 STX1A NME2 CRP ITIH4 CLIC1 72 BDNF MMP7 GHR TGFBI CHRDL1 0.942 SERPINA1 AHSG STX1A TPI1 CLIC1 73 BDNF CDH1 MMP7 GHR CHRDL1 0.942 AHSG STX1A PA2G4 CRP CLIC1 74 BDNF MMP7 GHR TGFBI CHRDL1 0.942 STX1A GPI TPI1 CRP CLIC1 75 BDNF HMGB1 MMP7 GHR TGFBI 0.942 CHRDL1 AHSG STX1A CRP CLIC1 76 BDNF MMP7 GHR TGFBI CHRDL1 0.942 STX1A NME2 GPI CRP CLIC1 77 KLK3-SERPINA3 BDNF KIT MMP7 GHR 0.942 TGFBI LRIG3 CHRDL1 TPI1 CLIC1 78 BDNF KIT MMP7 GHR TGFBI 0.942 LRIG3 CHRDL1 NME2 CRP CLIC1 79 BDNF MMP7 GHR C9 TGFBI 0.942 CHRDL1 AHSG TPI1 CRP CLIC1 80 BDNF MMP7 GHR C9 CHRDL1 0.942 AHSG STX1A GPI TPI1 CLIC1 81 BDNF EGFR MMP7 GHR TGFBI 0.942 CHRDL1 AHSG STX1A NME2 CLIC1 82 BDNF MMP7 GHR TGFBI LRIG3 0.941 STX1A NME2 CRP CLIC1 PLA2G7 83 BDNF MMP7 GHR C9 TGFBI 0.941 CHRDL1 AHSG STX1A TPT1 CLIC1 84 BDNF MMP7 GHR TGFBI CHRDL1 0.941 SERPINA1 STX1A PA2G4 GPI CLIC1 85 BDNF MMP7 GHR TGFBI CHRDL1 0.941 AHSG STX1A PA2G4 GPI CLIC1 86 KLK3-SERPINA3 BDNF KIT MMP7 GHR 0.941 LRIG3 STX1A NME2 GPI CLIC1 87 KLK3-SERPINA3 BDNF MMP7 GHR LRIG3 0.941 CHRDL1 AHSG STX1A TPI1 CLIC1 88 KLK3-SERPINA3 BDNF MMP7 GHR CNTN1 0.941 TGFBI CHRDL1 STX1A PA2G4 CLIC1 89 BDNF MMP7 GHR C9 CHRDL1 0.941 STX1A NME2 PA2G4 ITIH4 CLIC1 90 BDNF IGFBP2 MMP7 GHR TGFBI 0.941 AHSG STX1A TPI1 CRP CLIC1 91 BDNF MMP7 GHR C9 TGFBI 0.941 CHRDL1 GPI TPI1 CRP CLIC1 92 BDNF MMP7 GHR TGFBI LRIG3 0.941 CHRDL1 STX1A TPT1 CRP CLIC1 93 KLK3-SERPINA3 BDNF MMP7 GHR TGFBI 0.941 LRIG3 STX1A NME2 CRP CLIC1 94 BDNF EGFR MMP7 GHR TGFBI 0.941 CHRDL1 STX1A NME2 CRP CLIC1 95 BDNF KIT MMP7 GHR C9 0.941 LRIG3 STX1A NME2 CRP CLIC1 96 BDNF CDH1 MMP7 GHR TGFBI 0.941 LRIG3 AHSG STX1A CRP CLIC1 97 BDNF MMP7 GHR CHRDL1 AHSG 0.941 STX1A GPI TPI1 CRP CLIC1 98 BDNF KIT MMP7 GHR LRIG3 0.941 STX1A NME2 GPI CRP CLIC1 99 KLK3-SERPINA3 BDNF MMP7 GHR TGFBI 0.941 AHSG STX1A TPI1 CRP CLIC1 100 BDNF MMP7 GHR C9 CHRDL1 0.941 AHSG STX1A NME2 GPI CLIC1

TABLE 12 Counts of markers in biomarker panels Panel Size Biomarker 3 4 5 6 7 8 9 10 AHSG 37 45 59 85 116 159 222 349 AKR7A2 87 48 23 9 3 3 1 0 AKT3 0 0 0 0 0 0 0 1 BDNF 53 129 332 583 801 953 988 995 BMP1 81 93 84 74 42 32 26 23 BMPER 13 1 0 0 0 0 0 0 C9 131 178 252 244 233 211 203 194 CA6 29 14 1 0 0 0 0 0 CAPG 6 0 0 0 0 0 0 0 CDH1 22 56 104 105 112 129 145 166 CHRDL1 50 61 81 98 116 170 304 477 CKB-CKM 26 18 8 8 6 2 0 1 CLIC1 260 447 669 883 978 994 1000 1000 CMA1 84 119 189 158 99 62 37 19 CNTN1 20 52 61 59 42 30 31 29 COL18A1 25 17 7 0 1 0 0 0 CRP 74 89 95 112 153 200 308 454 CTSL2 2 0 0 0 0 0 0 0 DDC 37 23 7 5 4 0 0 0 EGFR 63 47 27 41 50 88 100 121 FGA-FGB- 23 0 0 0 0 0 0 0 FGG FN1 3 0 0 2 0 2 8 18 GHR 32 67 159 315 452 587 745 850 GPI 71 79 103 147 167 183 202 225 HMGB1 15 36 11 17 19 4 6 4 HNRNPAB 46 27 35 45 60 41 38 32 HP 21 7 0 0 0 0 0 0 HSP90AA1 2 0 0 0 0 0 0 0 HSPA1A 6 2 0 0 0 0 0 0 IGFBP2 42 51 74 105 142 129 91 67 IGFBP4 19 6 1 3 2 0 5 6 ITIH4 23 46 51 64 117 163 180 208 KIT 21 26 30 51 109 203 295 327 KLK3- 111 188 262 287 307 338 377 378 SERPINA3 L1CAM 41 45 44 16 9 8 3 8 LRIG3 109 161 241 293 330 367 376 407 MMP12 71 29 5 2 0 0 0 0 MMP7 270 626 782 852 916 960 982 996 NME2 83 77 112 159 189 251 282 299 PA2G4 7 33 41 57 85 146 203 275 PLA2G7 17 32 28 30 47 67 70 66 PLAUR 33 22 11 5 0 0 0 0 PRKACA 8 0 0 0 0 0 0 0 PRKCB 3 0 0 0 0 0 0 0 PROK11 2 0 0 0 0 0 0 0 PRSS2 5 0 0 0 0 0 0 0 PTN 17 2 0 0 0 0 0 0 SERPINA1 51 35 23 16 29 36 43 68 STC1 17 10 7 4 4 8 8 7 STX1A 131 268 345 520 691 823 902 934 TACSTD2 7 1 2 0 1 0 0 3 TGFBI 62 98 136 191 266 339 462 579 TPI1 42 64 106 124 139 187 243 305 TPT1 54 33 22 29 67 88 108 108 YWHAG 419 492 369 202 96 37 6 1 YWHAH 16 0 1 0 0 0 0 0

TABLE 13 Analytes in ten marker classifiers CLIC1 BDNF MMP7 STX1A GHR TGFBI CHRDL1 CRP LRIG3 KLK3-SERPINA3 AHSG KIT

TABLE 14 Parameters derived from training set for naïve Bayes classifier. Biomarker μ_(c) μ_(d) σ_(c) σ_(d) BMPER 7.450 7.323 0.108 0.164 COL18A1 8.763 8.876 0.125 0.162 CMA1 6.800 6.754 0.047 0.041 MMP7 8.881 9.232 0.235 0.182 KIT 9.603 9.503 0.139 0.141 IGFBP2 8.514 9.006 0.417 0.448 PROK11 6.196 6.154 0.042 0.058 DDC 6.746 6.711 0.034 0.043 PRKACA 7.594 7.753 0.187 0.113 FGA-FGB-FGG 9.836 10.258 0.338 0.580 CNTN1 9.265 9.149 0.181 0.114 CRP 7.733 9.005 1.095 1.422 HNRNPAB 7.252 7.517 0.304 0.225 HSP90AA1 9.165 9.343 0.226 0.182 PLA2G7 10.131 9.952 0.277 0.184 BDNF 6.931 6.854 0.102 0.068 AKR7A2 6.761 7.155 0.432 0.248 IGFBP4 8.138 8.268 0.140 0.163 PLAUR 8.248 8.385 0.133 0.178 C9 11.715 11.936 0.189 0.223 SERPINA1 10.215 10.371 0.169 0.239 STC1 8.475 8.691 0.242 0.293 HP 11.848 12.057 0.222 0.196 L1CAM 7.893 7.721 0.226 0.152 ITIH4 10.596 10.738 0.121 0.227 BMP1 8.766 8.548 0.213 0.234 TFF3 8.288 8.536 0.195 0.307 PRKCB 6.817 6.780 0.051 0.060 IL12B-IL23A 6.189 6.153 0.037 0.039 CLIC1 7.907 8.260 0.259 0.230 CDH1 9.252 9.050 0.200 0.181 CHRDL1 8.665 8.938 0.215 0.388 EGFR 10.578 10.428 0.119 0.135 ASGR1 6.661 6.619 0.050 0.052 TACSTD2 6.879 6.849 0.040 0.043 PRSS2 10.080 10.457 0.421 0.529 AKT3 7.816 7.886 0.074 0.068 HMGB1 8.430 8.546 0.133 0.096 CAPG 7.271 7.602 0.272 0.277 YWHAH 7.644 7.774 0.107 0.105 PTN 8.149 8.250 0.116 0.152 YWHAG 8.156 8.496 0.205 0.187 CTSL2 6.262 6.207 0.063 0.069 GHR 7.724 7.595 0.135 0.102 TGFBI 9.944 9.777 0.178 0.239 GPI 7.506 7.760 0.278 0.260 TPI1 9.087 9.392 0.450 0.221 STX1A 7.186 7.143 0.035 0.033 LRIG3 7.411 7.301 0.090 0.092 TPT1 8.847 9.137 0.290 0.224 PA2G4 7.735 8.026 0.643 0.329 NME2 6.333 6.618 0.339 0.242 CKB-CKM 7.515 7.230 0.317 0.307 CA6 7.180 7.038 0.228 0.108 AHSG 11.197 11.107 0.149 0.134 KLK3-SERPINA3 8.102 8.327 0.194 0.330 FN1 9.286 9.058 0.239 0.325 MMP12 6.129 6.323 0.100 0.260 HSPA1A 8.819 9.011 0.316 0.224

TABLE 15 AUC for exemplary combinations of biomarkers # AUC 1 MMP7 0.803 2 MMP7 CLIC1 0.883 3 MMP7 CLIC1 STX1A 0.901 4 MMP7 CLIC1 STX1A CHRDL1 0.899 5 MMP7 CLIC1 STX1A CHRDL1 PA2G4 0.912 6 MMP7 CLIC1 STX1A CHRDL1 PA2G4 SERPINA1 0.922 7 MMP7 CLIC1 STX1A CHRDL1 PA2G4 SERPINA1 BDNF 0.930 8 MMP7 CLIC1 STX1A CHRDL1 PA2G4 SERPINA1 BDNF GHR 0.937 9 MMP7 CLIC1 STX1A CHRDL1 PA2G4 SERPINA1 BDNF GHR TGFBI 0.944 10 MMP7 CLIC1 STX1A CHRDL1 PA2G4 SERPINA1 BDNF GHR TGFBI NME2 0.948

TABLE 16 Calculations derived from training set for naïve Bayes classifier. Biomarker μ_(c) μ_(d) σ_(c) σ_(d) {tilde over (x)} p(c|{tilde over (x)}) p(d|{tilde over (x)}) ln(p(d|{tilde over (x)})/p(c|{tilde over (x)})) GHR 7.724 7.595 0.135 0.102 7.860 1.778 0.136 −2.572 SERPINA1 10.215 10.371 0.169 0.239 10.573 0.252 1.166 1.531 STX1A 7.186 7.143 0.035 0.033 7.259 1.382 0.024 −4.053 CHRDL1 8.665 8.938 0.215 0.388 8.405 0.896 0.401 −0.804 CLIC1 7.907 8.260 0.259 0.230 8.068 1.267 1.226 −0.034 PA2G4 7.735 8.026 0.643 0.329 7.285 0.486 0.096 −1.622 NME2 6.333 6.618 0.339 0.242 6.322 1.175 0.783 −0.406 MMP7 8.881 9.232 0.235 0.182 8.684 1.194 0.023 −3.942 TGFBI 9.944 9.777 0.178 0.239 9.778 1.446 1.669 0.144 BDNF 6.931 6.854 0.102 0.068 6.904 3.768 4.484 0.174

TABLE 17 Clinical characteristics of the training set Meta Data Levels Control Disease p-value Samples 218 46 GENDER F 118 36 M 100 10 4.34e−03 AGE Mean 57.2 67.3 SD 10.2 10.8 2.35e−07 CANCER STAGE I 0 26 II 0 4 III 0 7 IV 0 9 NaN TOBACCO USER Never 1 2 Not Reported 3 10 Past 84 24 Current 130 10 1.27e−10

TABLE 18 Ten biomarker classifier proteins Biomarker UniProt ID Direction* Biological Process (GO) BDNF P23560 Down response to stress cell communication regulation of cell death signaling process MMP7 P09237 Up proteolysis GHR P10912 Down regulation of cell death signaling process signaling regulation of signaling pathway TGFBI Q15582 Down cell proliferation regulation of cell adhesion CHRDL1 Q9BU40 Up signaling SERPINA1 P01009 Up response to stress STX1A Q16623 Down cell communication signaling NME2 P22392 Up PA2G4 Q9UQ80 Up cell proliferation CLIC1 O00299 Up signaling process

TABLE 19 Biomarkers of general cancer KLK3-SERPINA3 EGFR BMPER FGA-FGB-FGG C9 STX1A AKR7A2 CKB-CKM DDC CA6 IGFBP2 IGFBP4 FN1 BMP1 CRP KIT CNTN1 SERPINA1 BDNF GHR ITIH4 NME2 AHSG

TABLE 20 Panels of 1 Biomarker Markers Mean CV AUC 1 C9 0.792 2 KLK3-SERPINA3 0.782 3 CRP 0.763 4 BMPER 0.745 5 BMP1 0.732 6 KIT 0.729 7 AKR7A2 0.726 8 EGFR 0.726 9 ITIH4 0.721 10 IGFBP2 0.720 11 BDNF 0.720 12 STX1A 0.719 13 NME2 0.714 14 FGA-FGB-FGG 0.712 15 CNTN1 0.708 16 CKB-CKM 0.708 17 AHSG 0.707 18 GHR 0.704 19 IGFBP4 0.703 20 CA6 0.700 21 DDC 0.696 22 FN1 0.694 23 SERPINA1 0.688

TABLE 21 Panels of 2 Biomarkers Markers Mean CV AUC 1 C9 AKR7A2 0.832 2 KLK3-SERPINA3 AKR7A2 0.831 3 KLK3-SERPINA3 NME2 0.828 4 AKR7A2 CRP 0.827 5 KLK3-SERPINA3 EGFR 0.826 6 KLK3-SERPINA3 STX1A 0.826 7 C9 NME2 0.824 8 KLK3-SERPINA3 BDNF 0.823 9 KLK3-SERPINA3 IGFBP4 0.822 10 KLK3-SERPINA3 CA6 0.819 11 KIT C9 0.819 12 BDNF C9 0.818 13 KLK3-SERPINA3 BMP1 0.816 14 KLK3-SERPINA3 BMPER 0.816 15 NME2 CRP 0.815 16 KLK3-SERPINA3 KIT 0.815 17 C9 BMPER 0.814 18 BMPER NME2 0.812 19 KLK3-SERPINA3 C9 0.811 20 KLK3-SERPINA3 CRP 0.811 21 C9 STX1A 0.811 22 EGFR C9 0.811 23 BMPER AKR7A2 0.810 24 BMPER CRP 0.810 25 BDNF CRP 0.810 26 C9 DDC 0.809 27 KLK3-SERPINA3 CNTN1 0.809 28 KLK3-SERPINA3 IGFBP2 0.808 29 SERPINA1 AKR7A2 0.808 30 AKR7A2 ITIH4 0.808 31 C9 AHSG 0.807 32 IGFBP4 C9 0.807 33 KLK3-SERPINA3 DDC 0.807 34 BMP1 AKR7A2 0.806 35 CNTN1 C9 0.806 36 STX1A CRP 0.805 37 IGFBP2 CRP 0.805 38 NME2 ITIH4 0.805 39 BMP1 CRP 0.805 40 KLK3-SERPINA3 AHSG 0.804 41 C9 CA6 0.803 42 C9 CRP 0.802 43 GHR C9 0.802 44 BDNF AKR7A2 0.802 45 KLK3-SERPINA3 FN1 0.801 46 BDNF KIT 0.801 47 KLK3-SERPINA3 GHR 0.799 48 EGFR ITIH4 0.799 49 C9 BMP1 0.798 50 KIT CRP 0.798 51 IGFBP2 C9 0.798 52 BMP1 NME2 0.797 53 C9 ITIH4 0.797 54 EGFR AKR7A2 0.797 55 NME2 FGA-FGB-FGG 0.796 56 EGFR CRP 0.795 57 IGFBP2 AKR7A2 0.795 58 STX1A ITIH4 0.795 59 SERPINA1 NME2 0.795 60 KIT AKR7A2 0.795 61 IGFBP2 BMPER 0.794 62 CNTN1 AKR7A2 0.794 63 C9 FN1 0.794 64 AKR7A2 FGA-FGB-FGG 0.793 65 BDNF NME2 0.793 66 GHR CRP 0.792 67 AHSG AKR7A2 0.792 68 CNTN1 BMPER 0.791 69 KIT BMP1 0.791 70 CNTN1 BMP1 0.791 71 KIT BMPER 0.790 72 KLK3-SERPINA3 ITIH4 0.790 73 DDC CRP 0.789 74 CA6 CRP 0.788 75 IGFBP4 AKR7A2 0.788 76 IGFBP4 CRP 0.788 77 GHR BMPER 0.787 78 IGFBP2 CNTN1 0.787 79 EGFR NME2 0.787 80 BMPER ITIH4 0.786 81 BDNF CNTN1 0.785 82 C9 CKB-CKM 0.785 83 GHR AKR7A2 0.785 84 FN1 CRP 0.784 85 BDNF BMPER 0.784 86 CNTN1 CRP 0.784 87 KLK3-SERPINA3 CKB-CKM 0.784 88 EGFR AHSG 0.783 89 EGFR BMPER 0.783 90 STX1A NME2 0.783 91 BMP1 BMPER 0.783 92 DDC ITIH4 0.783 93 CA6 BMPER 0.782 94 STX1A AKR7A2 0.781 95 CRP ITIH4 0.781 96 BDNF ITIH4 0.780 97 IGFBP2 ITIH4 0.780 98 AHSG NME2 0.779 99 CNTN1 NME2 0.779 100 CA6 AKR7A2 0.778

TABLE 22 Panels of 3 Biomarkers Markers Mean CV AUC 1 IGFBP2 AKR7A2 CRP 0.849 2 KLK3-SERPINA3 BMPER NME2 0.849 3 KLK3-SERPINA3 C9 AKR7A2 0.848 4 KLK3-SERPINA3 AKR7A2 CRP 0.848 5 KLK3-SERPINA3 EGFR AKR7A2 0.848 6 BMP1 AKR7A2 CRP 0.848 7 C9 BMPER AKR7A2 0.848 8 C9 BMPER NME2 0.848 9 KLK3-SERPINA3 BMP1 AKR7A2 0.847 10 C9 AKR7A2 CRP 0.847 11 KLK3-SERPINA3 BMP1 NME2 0.847 12 BDNF KIT C9 0.846 13 BDNF C9 AKR7A2 0.845 14 KLK3-SERPINA3 EGFR NME2 0.845 15 BMPER NME2 CRP 0.845 16 BMPER AKR7A2 CRP 0.845 17 KLK3-SERPINA3 BMPER AKR7A2 0.845 18 KLK3-SERPINA3 BDNF AKR7A2 0.844 19 KIT C9 AKR7A2 0.844 20 KLK3-SERPINA3 NME2 CRP 0.844 21 EGFR C9 AKR7A2 0.844 22 BDNF AKR7A2 CRP 0.844 23 KLK3-SERPINA3 IGFBP4 AKR7A2 0.843 24 CNTN1 C9 AKR7A2 0.843 25 KLK3-SERPINA3 CA6 AKR7A2 0.843 26 C9 AHSG AKR7A2 0.843 27 KLK3-SERPINA3 IGFBP2 AKR7A2 0.843 28 KLK3-SERPINA3 BDNF KIT 0.842 29 KLK3-SERPINA3 C9 NME2 0.842 30 KLK3-SERPINA3 CNTN1 AKR7A2 0.842 31 KLK3-SERPINA3 BDNF NME2 0.841 32 BMP1 NME2 CRP 0.841 33 KLK3-SERPINA3 KIT AKR7A2 0.841 34 KIT AKR7A2 CRP 0.841 35 BMPER NME2 ITIH4 0.840 36 EGFR AKR7A2 CRP 0.840 37 KLK3-SERPINA3 STX1A AKR7A2 0.840 38 IGFBP4 C9 AKR7A2 0.839 39 KLK3-SERPINA3 IGFBP4 NME2 0.839 40 KLK3-SERPINA3 CNTN1 NME2 0.839 41 C9 DDC AKR7A2 0.839 42 BDNF C9 NME2 0.839 43 GHR AKR7A2 CRP 0.839 44 C9 BMP1 AKR7A2 0.839 45 KLK3-SERPINA3 BDNF CNTN1 0.838 46 KLK3-SERPINA3 STX1A NME2 0.838 47 IGFBP2 C9 AKR7A2 0.838 48 GHR C9 AKR7A2 0.838 49 C9 AKR7A2 ITIH4 0.838 50 BMP1 BMPER NME2 0.837 51 BDNF KIT CRP 0.837 52 C9 STX1A AKR7A2 0.837 53 BDNF NME2 CRP 0.837 54 KLK3-SERPINA3 AKR7A2 ITIH4 0.837 55 C9 NME2 CRP 0.836 56 C9 NME2 ITIH4 0.836 57 BMP1 BMPER AKR7A2 0.836 58 KLK3-SERPINA3 BDNF C9 0.836 59 KLK3-SERPINA3 AHSG AKR7A2 0.836 60 KLK3-SERPINA3 CA6 NME2 0.835 61 KLK3-SERPINA3 GHR AKR7A2 0.835 62 KIT C9 NME2 0.835 63 KLK3-SERPINA3 CNTN1 BMP1 0.835 64 C9 AHSG NME2 0.835 65 BDNF KIT AKR7A2 0.835 66 KLK3-SERPINA3 IGFBP2 NME2 0.835 67 STX1A AKR7A2 CRP 0.835 68 KLK3-SERPINA3 KIT STX1A 0.835 69 KLK3-SERPINA3 NME2 ITIH4 0.835 70 KLK3-SERPINA3 SERPINA1 AKR7A2 0.834 71 IGFBP4 AKR7A2 CRP 0.834 72 IGFBP2 BMPER AKR7A2 0.834 73 EGFR C9 NME2 0.834 74 KLK3-SERPINA3 BDNF CRP 0.834 75 KLK3-SERPINA3 STX1A CRP 0.834 76 GHR BMPER AKR7A2 0.833 77 IGFBP2 NME2 CRP 0.833 78 KLK3-SERPINA3 CNTN1 BMPER 0.833 79 KLK3-SERPINA3 KIT BMP1 0.833 80 KLK3-SERPINA3 BDNF EGFR 0.833 81 CNTN1 C9 NME2 0.833 82 KLK3-SERPINA3 KIT NME2 0.833 83 KLK3-SERPINA3 BDNF STX1A 0.833 84 KLK3-SERPINA3 AHSG NME2 0.833 85 CNTN1 AKR7A2 CRP 0.833 86 C9 SERPINA1 AKR7A2 0.833 87 KLK3-SERPINA3 C9 STX1A 0.833 88 KLK3-SERPINA3 BDNF CA6 0.833 89 EGFR AKR7A2 ITIH4 0.833 90 KLK3-SERPINA3 KIT EGFR 0.833 91 C9 DDC NME2 0.833 92 KLK3-SERPINA3 DDC AKR7A2 0.833 93 CNTN1 BMP1 AKR7A2 0.832 94 AKR7A2 CRP ITIH4 0.832 95 KLK3-SERPINA3 EGFR ITIH4 0.832 96 CNTN1 BMPER AKR7A2 0.832 97 KLK3-SERPINA3 EGFR AHSG 0.832 98 KLK3-SERPINA3 BDNF IGFBP4 0.832 99 IGFBP4 SERPINA1 AKR7A2 0.832 100 SERPINA1 BMPER AKR7A2 0.832

TABLE 23 Panels of 4 Biomarkers Mean CV Markers AUC 1 BDNF KIT AKR7A2 CRP 0.860 2 KLK3-SERPINA3 CNTN1 BMPER NME2 0.860 3 BDNF KIT C9 AKR7A2 0.859 4 KLK3-SERPINA3 BMP1 BMPER NME2 0.859 5 KIT BMP1 AKR7A2 CRP 0.859 6 KLK3-SERPINA3 BMP1 NME2 CRP 0.858 7 KLK3-SERPINA3 CNTN1 BMP1 NME2 0.858 8 KLK3-SERPINA3 EGFR AKR7A2 CRP 0.857 9 KLK3-SERPINA3 C9 BMPER AKR7A2 0.857 10 KLK3-SERPINA3 KIT C9 AKR7A2 0.857 11 KLK3-SERPINA3 BMP1 AKR7A2 CRP 0.857 12 KLK3-SERPINA3 IGFBP2 AKR7A2 CRP 0.857 13 C9 BMPER AKR7A2 CRP 0.857 14 KLK3-SERPINA3 IGFBP4 C9 AKR7A2 0.857 15 GHR BMPER AKR7A2 CRP 0.857 16 CNTN1 C9 BMPER AKR7A2 0.857 17 BDNF IGFBP2 AKR7A2 CRP 0.857 18 KIT C9 AKR7A2 CRP 0.857 19 IGFBP2 BMPER AKR7A2 CRP 0.857 20 KLK3-SERPINA3 EGFR C9 AKR7A2 0.856 21 KLK3-SERPINA3 CNTN1 BMP1 AKR7A2 0.856 22 KLK3-SERPINA3 CNTN1 C9 AKR7A2 0.856 23 KLK3-SERPINA3 IGFBP4 AKR7A2 CRP 0.856 24 KLK3-SERPINA3 C9 BMPER NME2 0.856 25 KLK3-SERPINA3 KIT BMP1 AKR7A2 0.856 26 KLK3-SERPINA3 BMPER NME2 CRP 0.856 27 GHR C9 BMPER AKR7A2 0.856 28 CNTN1 C9 BMPER NME2 0.856 29 GHR BMPER NME2 CRP 0.855 30 KLK3-SERPINA3 BDNF KIT AKR7A2 0.855 31 BDNF C9 AKR7A2 CRP 0.855 32 KLK3-SERPINA3 C9 AKR7A2 CRP 0.855 33 KLK3-SERPINA3 BDNF AKR7A2 CRP 0.855 34 IGFBP2 BMPER NME2 CRP 0.855 35 KLK3-SERPINA3 CNTN1 BMPER AKR7A2 0.855 36 KLK3-SERPINA3 BMPER AKR7A2 CRP 0.855 37 BMP1 BMPER AKR7A2 CRP 0.855 38 KLK3-SERPINA3 EGFR BMPER NME2 0.855 39 CNTN1 C9 BMP1 AKR7A2 0.855 40 KLK3-SERPINA3 KIT AKR7A2 CRP 0.854 41 KLK3-SERPINA3 GHR BMPER NME2 0.854 42 KLK3-SERPINA3 IGFBP4 BMPER NME2 0.854 43 IGFBP2 C9 AKR7A2 CRP 0.854 44 KLK3-SERPINA3 IGFBP2 CNTN1 AKR7A2 0.854 45 KLK3-SERPINA3 BDNF C9 AKR7A2 0.854 46 GHR C9 BMPER NME2 0.854 47 KLK3-SERPINA3 BMPER NME2 ITIH4 0.854 48 KIT IGFBP2 AKR7A2 CRP 0.854 49 KLK3-SERPINA3 EGFR NME2 CRP 0.854 50 KIT C9 BMPER AKR7A2 0.854 51 KIT EGFR C9 AKR7A2 0.854 52 BMP1 BMPER NME2 CRP 0.854 53 KLK3-SERPINA3 IGFBP2 BMPER AKR7A2 0.853 54 EGFR C9 AHSG AKR7A2 0.853 55 KLK3-SERPINA3 EGFR NME2 ITIH4 0.853 56 IGFBP2 CNTN1 AKR7A2 CRP 0.853 57 C9 BMPER NME2 ITIH4 0.853 58 IGFBP2 BMP1 AKR7A2 CRP 0.853 59 KLK3-SERPINA3 CNTN1 AKR7A2 CRP 0.853 60 KLK3-SERPINA3 IGFBP4 C9 NME2 0.853 61 KLK3-SERPINA3 IGFBP2 BMPER NME2 0.853 62 KLK3-SERPINA3 IGFBP4 SERPINA1 AKR7A2 0.853 63 BDNF CNTN1 C9 AKR7A2 0.853 64 CNTN1 BMP1 AKR7A2 CRP 0.853 65 KLK3-SERPINA3 BDNF CNTN1 AKR7A2 0.853 66 BDNF KIT C9 NME2 0.853 67 KLK3-SERPINA3 CNTN1 C9 NME2 0.853 68 KLK3-SERPINA3 EGFR BMPER AKR7A2 0.853 69 KLK3-SERPINA3 IGFBP4 AKR7A2 ITIH4 0.853 70 KLK3-SERPINA3 IGFBP4 NME2 CRP 0.853 71 KLK3-SERPINA3 IGFBP4 BMP1 AKR7A2 0.852 72 EGFR C9 AKR7A2 ITIH4 0.852 73 EGFR C9 AKR7A2 CRP 0.852 74 KLK3-SERPINA3 KIT BMP1 NME2 0.852 75 KLK3-SERPINA3 KIT EGFR AKR7A2 0.852 76 KLK3-SERPINA3 EGFR AKR7A2 ITIH4 0.852 77 KLK3-SERPINA3 BDNF NME2 CRP 0.852 78 IGFBP4 C9 AKR7A2 ITIH4 0.852 79 KLK3-SERPINA3 GHR BMPER AKR7A2 0.852 80 KLK3-SERPINA3 BMP1 BMPER AKR7A2 0.852 81 IGFBP2 C9 BMPER AKR7A2 0.852 82 BDNF KIT NME2 CRP 0.852 83 KLK3-SERPINA3 KIT C9 NME2 0.852 84 IGFBP2 AKR7A2 CRP ITIH4 0.852 85 C9 BMPER AKR7A2 ITIH4 0.852 86 KLK3-SERPINA3 EGFR BMP1 AKR7A2 0.852 87 KLK3-SERPINA3 C9 CA6 AKR7A2 0.852 88 KLK3-SERPINA3 NME2 CRP ITIH4 0.852 89 EGFR CNTN1 C9 AKR7A2 0.852 90 KLK3-SERPINA3 C9 STX1A AKR7A2 0.852 91 C9 BMPER NME2 CRP 0.852 92 KIT CNTN1 C9 AKR7A2 0.852 93 KLK3-SERPINA3 IGFBP4 BMPER AKR7A2 0.851 94 KIT C9 BMP1 AKR7A2 0.851 95 KLK3-SERPINA3 KIT BMPER NME2 0.851 96 KLK3-SERPINA3 CNTN1 NME2 CRP 0.851 97 KLK3-SERPINA3 BDNF KIT NME2 0.851 98 BDNF C9 AHSG AKR7A2 0.851 99 KLK3-SERPINA3 BDNF EGFR AKR7A2 0.851 100 KIT C9 BMPER NME2 0.851

TABLE 24 Panels of 5 Biomarkers Markers Mean CV AUC 1 KLK3-SERPINA3 CNTN1 C9 BMPER AKR7A2 0.866 2 BDNF KIT C9 AKR7A2 CRP 0.866 3 KLK3-SERPINA3 CNTN1 BMP1 BMPER NME2 0.865 4 KLK3-SERPINA3 IGFBP2 CNTN1 AKR7A2 CRP 0.865 5 KLK3-SERPINA3 IGFBP2 CNTN1 BMPER AKR7A2 0.865 6 BDNF KIT IGFBP2 AKR7A2 CRP 0.865 7 KLK3-SERPINA3 BDNF KIT AKR7A2 CRP 0.865 8 KLK3-SERPINA3 IGFBP2 CNTN1 BMPER NME2 0.865 9 KLK3-SERPINA3 CNTN1 BMP1 NME2 CRP 0.865 10 KLK3-SERPINA3 KIT CNTN1 BMP1 AKR7A2 0.864 11 KLK3-SERPINA3 KIT C9 BMPER AKR7A2 0.864 12 KLK3-SERPINA3 KIT BMP1 AKR7A2 CRP 0.864 13 BDNF KIT BMP1 AKR7A2 CRP 0.864 14 KLK3-SERPINA3 KIT CNTN1 BMP1 NME2 0.864 15 KLK3-SERPINA3 KIT C9 BMPER NME2 0.864 16 GHR C9 BMPER AKR7A2 CRP 0.864 17 KLK3-SERPINA3 EGFR NME2 CRP ITIH4 0.864 18 KLK3-SERPINA3 KIT BMP1 BMPER NME2 0.864 19 KLK3-SERPINA3 KIT CNTN1 C9 AKR7A2 0.864 20 KLK3-SERPINA3 BDNF KIT C9 AKR7A2 0.864 21 KLK3-SERPINA3 IGFBP4 C9 BMPER AKR7A2 0.863 22 KIT GHR C9 BMPER AKR7A2 0.863 23 KLK3-SERPINA3 CNTN1 BMPER AKR7A2 CRP 0.863 24 KLK3-SERPINA3 BDNF KIT CNTN1 AKR7A2 0.863 25 KLK3-SERPINA3 KIT IGFBP4 C9 AKR7A2 0.863 26 KLK3-SERPINA3 CNTN1 BMP1 AKR7A2 CRP 0.863 27 KLK3-SERPINA3 C9 BMPER AKR7A2 ITIH4 0.863 28 KIT BMP1 BMPER AKR7A2 CRP 0.863 29 KIT CNTN1 C9 BMP1 AKR7A2 0.863 30 KLK3-SERPINA3 KIT CNTN1 BMPER NME2 0.863 31 KLK3-SERPINA3 IGFBP2 BMPER AKR7A2 CRP 0.863 32 KLK3-SERPINA3 CNTN1 C9 BMPER NME2 0.863 33 KIT C9 BMPER AKR7A2 CRP 0.863 34 KLK3-SERPINA3 CNTN1 BMP1 BMPER AKR7A2 0.863 35 KLK3-SERPINA3 IGFBP4 CNTN1 C9 AKR7A2 0.862 36 KIT GHR BMPER AKR7A2 CRP 0.862 37 GHR CNTN1 C9 BMPER AKR7A2 0.862 38 KLK3-SERPINA3 CNTN1 BMPER NME2 CRP 0.862 39 KLK3-SERPINA3 GHR BMPER AKR7A2 CRP 0.862 40 BDNF KIT CNTN1 C9 AKR7A2 0.862 41 KLK3-SERPINA3 C9 BMPER AKR7A2 CRP 0.862 42 KLK3-SERPINA3 GHR C9 BMPER AKR7A2 0.862 43 KLK3-SERPINA3 IGFBP4 C9 AKR7A2 ITIH4 0.862 44 KLK3-SERPINA3 CNTN1 C9 BMP1 AKR7A2 0.862 45 KLK3-SERPINA3 KIT CNTN1 C9 NME2 0.862 46 IGFBP2 CNTN1 C9 BMPER AKR7A2 0.862 47 IGFBP2 CNTN1 BMPER AKR7A2 CRP 0.862 48 KLK3-SERPINA3 KIT IGFBP2 AKR7A2 CRP 0.862 49 KLK3-SERPINA3 IGFBP4 BMP1 NME2 CRP 0.862 50 KLK3-SERPINA3 IGFBP4 BMP1 AKR7A2 CRP 0.862 51 KIT GHR BMP1 AKR7A2 CRP 0.862 52 KIT IGFBP2 C9 AKR7A2 CRP 0.862 53 KLK3-SERPINA3 BDNF CNTN1 C9 AKR7A2 0.862 54 KLK3-SERPINA3 IGFBP2 BMPER NME2 CRP 0.862 55 KLK3-SERPINA3 EGFR AKR7A2 CRP ITIH4 0.862 56 KLK3-SERPINA3 EGFR CNTN1 C9 AKR7A2 0.862 57 KLK3-SERPINA3 KIT BMP1 NME2 CRP 0.861 58 KLK3-SERPINA3 IGFBP4 BMPER AKR7A2 CRP 0.861 59 KLK3-SERPINA3 KIT C9 AKR7A2 CRP 0.861 60 KLK3-SERPINA3 KIT EGFR AKR7A2 CRP 0.861 61 KLK3-SERPINA3 IGFBP4 C9 BMPER NME2 0.861 62 KLK3-SERPINA3 KIT C9 BMP1 AKR7A2 0.861 63 KIT GHR C9 AKR7A2 CRP 0.861 64 KLK3-SERPINA3 C9 DDC BMPER AKR7A2 0.861 65 KLK3-SERPINA3 IGFBP2 CNTN1 NME2 CRP 0.861 66 KIT CNTN1 C9 BMPER AKR7A2 0.861 67 KLK3-SERPINA3 KIT EGFR C9 AKR7A2 0.861 68 KLK3-SERPINA3 CNTN1 BMPER AKR7A2 ITIH4 0.861 69 KLK3-SERPINA3 EGFR C9 BMPER AKR7A2 0.861 70 CNTN1 C9 BMPER AKR7A2 CRP 0.861 71 KIT GHR BMPER NME2 CRP 0.861 72 IGFBP2 C9 BMPER AKR7A2 CRP 0.861 73 KLK3-SERPINA3 GHR BMPER NME2 CRP 0.861 74 KLK3-SERPINA3 IGFBP2 CNTN1 C9 AKR7A2 0.861 75 BDNF IGFBP2 CNTN1 AKR7A2 CRP 0.861 76 IGFBP2 CNTN1 BMP1 AKR7A2 CRP 0.861 77 BDNF KIT C9 BMPER AKR7A2 0.861 78 KLK3-SERPINA3 BDNF C9 AKR7A2 CRP 0.861 79 KIT IGFBP2 BMP1 AKR7A2 CRP 0.861 80 KLK3-SERPINA3 BMP1 BMPER NME2 CRP 0.861 81 KLK3-SERPINA3 BDNF IGFBP2 AKR7A2 CRP 0.861 82 KLK3-SERPINA3 IGFBP2 BMP1 AKR7A2 CRP 0.861 83 BDNF KIT GHR AKR7A2 CRP 0.861 84 KLK3-SERPINA3 IGFBP4 BMPER NME2 ITIH4 0.861 85 KLK3-SERPINA3 KIT BMPER NME2 CRP 0.861 86 KLK3-SERPINA3 IGFBP2 AKR7A2 CRP ITIH4 0.861 87 KLK3-SERPINA3 KIT BMPER AKR7A2 CRP 0.861 88 BDNF KIT C9 AHSG AKR7A2 0.860 89 IGFBP2 BMPER NME2 CRP ITIH4 0.860 90 KIT IGFBP2 BMPER AKR7A2 CRP 0.860 91 KLK3-SERPINA3 IGFBP4 BMPER NME2 CRP 0.860 92 KLK3-SERPINA3 KIT IGFBP4 AKR7A2 CRP 0.860 93 KLK3-SERPINA3 IGFBP2 EGFR AKR7A2 CRP 0.860 94 KLK3-SERPINA3 IGFBP4 CNTN1 C9 NME2 0.860 95 KLK3-SERPINA3 GHR CNTN1 BMPER NME2 0.860 96 KLK3-SERPINA3 IGFBP4 C9 AKR7A2 CRP 0.860 97 KLK3-SERPINA3 KIT CNTN1 BMPER AKR7A2 0.860 98 KIT C9 BMP1 AKR7A2 CRP 0.860 99 KLK3-SERPINA3 IGFBP2 C9 BMPER AKR7A2 0.860 100 KLK3-SERPINA3 EGFR C9 AKR7A2 CRP 0.860

TABLE 25 Panels of 6 Biomarkers Markers Mean CV AUC 1 KLK3-SERPINA3 KIT CNTN1 C9 BMPER 0.871 AKR7A2 2 KIT GHR C9 BMPER AKR7A2 0.871 CRP 3 KLK3-SERPINA3 BDNF KIT CNTN1 C9 0.871 AKR7A2 4 KLK3-SERPINA3 KIT CNTN1 C9 BMP1 0.871 AKR7A2 5 KLK3-SERPINA3 IGFBP2 CNTN1 BMPER AKR7A2 0.871 CRP 6 KLK3-SERPINA3 IGFBP4 CNTN1 C9 BMPER 0.871 AKR7A2 7 KLK3-SERPINA3 KIT CNTN1 C9 BMPER 0.870 NME2 8 KLK3-SERPINA3 KIT GHR C9 BMPER 0.870 AKR7A2 9 KLK3-SERPINA3 IGFBP2 CNTN1 C9 BMPER 0.870 AKR7A2 10 KLK3-SERPINA3 IGFBP2 CNTN1 BMPER AKR7A2 0.870 ITIH4 11 KLK3-SERPINA3 KIT IGFBP4 C9 BMPER 0.870 AKR7A2 12 KLK3-SERPINA3 KIT CNTN1 BMP1 BMPER 0.870 NME2 13 BDNF KIT IGFBP2 C9 AKR7A2 0.869 CRP 14 BDNF KIT GHR C9 AKR7A2 0.869 CRP 15 KLK3-SERPINA3 IGFBP2 CNTN1 BMP1 AKR7A2 0.869 CRP 16 KLK3-SERPINA3 KIT CNTN1 BMP1 NME2 0.869 CRP 17 KLK3-SERPINA3 KIT CNTN1 BMP1 BMPER 0.869 AKR7A2 18 BDNF KIT IGFBP2 CNTN1 AKR7A2 0.869 CRP 19 KIT GHR BMP1 BMPER AKR7A2 0.869 CRP 20 KLK3-SERPINA3 IGFBP2 CNTN1 BMPER NME2 0.869 CRP 21 KLK3-SERPINA3 CNTN1 C9 BMP1 BMPER 0.868 AKR7A2 22 KLK3-SERPINA3 IGFBP4 C9 BMPER AKR7A2 0.868 ITIH4 23 KLK3-SERPINA3 KIT IGFBP2 CNTN1 BMPER 0.868 AKR7A2 24 GHR CNTN1 C9 BMPER AKR7A2 0.868 CRP 25 KIT GHR CNTN1 C9 BMPER 0.868 AKR7A2 26 KLK3-SERPINA3 GHR CNTN1 C9 BMPER 0.868 AKR7A2 27 KLK3-SERPINA3 KIT IGFBP4 C9 AKR7A2 0.868 ITIH4 28 KLK3-SERPINA3 IGFBP4 CNTN1 BMPER AKR7A2 0.868 ITIH4 29 BDNF KIT IGFBP2 CNTN1 C9 0.867 AKR7A2 30 KIT CNTN1 C9 BMP1 BMPER 0.867 AKR7A2 31 KLK3-SERPINA3 BDNF KIT IGFBP2 AKR7A2 0.867 CRP 32 KLK3-SERPINA3 CNTN1 BMP1 BMPER AKR7A2 0.867 ITIH4 33 KLK3-SERPINA3 KIT GHR BMPER NME2 0.867 CRP 34 KLK3-SERPINA3 BDNF KIT C9 AKR7A2 0.867 CRP 35 KLK3-SERPINA3 KIT CNTN1 C9 BMP1 0.867 NME2 36 KLK3-SERPINA3 BDNF KIT CNTN1 AKR7A2 0.867 CRP 37 KLK3-SERPINA3 IGFBP4 CNTN1 C9 AKR7A2 0.867 ITIH4 38 KLK3-SERPINA3 CNTN1 C9 BMPER AKR7A2 0.867 ITIH4 39 KLK3-SERPINA3 BDNF KIT CNTN1 C9 0.867 NME2 40 KLK3-SERPINA3 KIT CNTN1 BMP1 AKR7A2 0.867 CRP 41 KLK3-SERPINA3 BDNF IGFBP2 CNTN1 AKR7A2 0.867 CRP 42 KLK3-SERPINA3 KIT IGFBP2 CNTN1 AKR7A2 0.867 CRP 43 KLK3-SERPINA3 IGFBP4 CNTN1 BMPER NME2 0.867 ITIH4 44 KLK3-SERPINA3 GHR CNTN1 BMPER AKR7A2 0.867 CRP 45 KLK3-SERPINA3 EGFR CNTN1 C9 BMPER 0.867 AKR7A2 46 KLK3-SERPINA3 KIT IGFBP2 BMPER AKR7A2 0.867 CRP 47 KIT IGFBP2 C9 BMPER AKR7A2 0.867 CRP 48 KLK3-SERPINA3 KIT EGFR C9 BMPER 0.867 AKR7A2 49 KLK3-SERPINA3 KIT IGFBP2 CNTN1 BMPER 0.867 NME2 50 KLK3-SERPINA3 KIT C9 BMP1 BMPER 0.867 AKR7A2 51 KLK3-SERPINA3 KIT GHR BMPER AKR7A2 0.867 CRP 52 KLK3-SERPINA3 CNTN1 BMP1 BMPER AKR7A2 0.867 CRP 53 BDNF KIT C9 BMPER AKR7A2 0.867 CRP 54 KIT GHR BMP1 BMPER NME2 0.867 CRP 55 KLK3-SERPINA3 IGFBP2 BMPER AKR7A2 CRP 0.867 ITIH4 56 KIT IGFBP2 CNTN1 C9 BMPER 0.867 AKR7A2 57 KLK3-SERPINA3 IGFBP4 CNTN1 BMP1 AKR7A2 0.867 ITIH4 58 KLK3-SERPINA3 KIT IGFBP4 CNTN1 C9 0.867 AKR7A2 59 KLK3-SERPINA3 IGFBP2 CNTN1 BMPER NME2 0.867 ITIH4 60 IGFBP2 CNTN1 C9 BMPER AKR7A2 0.866 CRP 61 KLK3-SERPINA3 KIT EGFR CNTN1 C9 0.866 AKR7A2 62 KLK3-SERPINA3 KIT IGFBP2 BMP1 AKR7A2 0.866 CRP 63 BDNF KIT CNTN1 C9 AKR7A2 0.866 CRP 64 KLK3-SERPINA3 KIT C9 BMPER AKR7A2 0.866 CRP 65 KLK3-SERPINA3 IGFBP4 CNTN1 BMP1 NME2 0.866 ITIH4 66 KLK3-SERPINA3 IGFBP4 BMP1 AKR7A2 CRP 0.866 ITIH4 67 KLK3-SERPINA3 KIT IGFBP4 BMP1 AKR7A2 0.866 CRP 68 KLK3-SERPINA3 GHR C9 BMPER AKR7A2 0.866 CRP 69 KLK3-SERPINA3 KIT BMP1 BMPER AKR7A2 0.866 CRP 70 KLK3-SERPINA3 IGFBP2 CNTN1 BMP1 BMPER 0.866 AKR7A2 71 KLK3-SERPINA3 IGFBP2 CNTN1 DDC BMPER 0.866 AKR7A2 72 KLK3-SERPINA3 KIT IGFBP2 CNTN1 C9 0.866 AKR7A2 73 KLK3-SERPINA3 KIT C9 DDC BMPER 0.866 AKR7A2 74 KLK3-SERPINA3 KIT CNTN1 BMPER AKR7A2 0.866 CRP 75 KLK3-SERPINA3 IGFBP4 CNTN1 BMP1 AKR7A2 0.866 CRP 76 KLK3-SERPINA3 KIT IGFBP4 CNTN1 BMP1 0.866 AKR7A2 77 KLK3-SERPINA3 BDNF KIT CNTN1 NME2 0.866 CRP 78 KLK3-SERPINA3 CNTN1 BMP1 AKR7A2 CRP 0.866 ITIH4 79 KIT IGFBP2 CNTN1 BMP1 AKR7A2 0.866 CRP 80 KLK3-SERPINA3 IGFBP2 CNTN1 BMP1 NME2 0.866 CRP 81 KLK3-SERPINA3 CNTN1 C9 BMPER AKR7A2 0.866 CRP 82 KLK3-SERPINA3 BDNF KIT CNTN1 BMP1 0.866 AKR7A2 83 KLK3-SERPINA3 IGFBP4 CNTN1 BMP1 NME2 0.866 CRP 84 KLK3-SERPINA3 IGFBP4 BMPER AKR7A2 CRP 0.866 ITIH4 85 KLK3-SERPINA3 IGFBP2 EGFR CNTN1 AKR7A2 0.866 CRP 86 BDNF KIT C9 AHSG AKR7A2 0.866 CRP 87 KLK3-SERPINA3 KIT IGFBP2 CNTN1 BMP1 0.866 AKR7A2 88 KLK3-SERPINA3 KIT BMP1 BMPER NME2 0.866 CRP 89 KLK3-SERPINA3 BDNF CNTN1 C9 AKR7A2 0.866 CRP 90 KLK3-SERPINA3 KIT CNTN1 BMPER NME2 0.866 ITIH4 91 KLK3-SERPINA3 IGFBP4 BMPER NME2 CRP 0.866 ITIH4 92 KIT IGFBP2 CNTN1 BMPER AKR7A2 0.866 CRP 93 KLK3-SERPINA3 IGFBP4 CNTN1 C9 BMPER 0.866 NME2 94 KLK3-SERPINA3 IGFBP4 CNTN1 C9 BMP1 0.866 AKR7A2 95 KLK3-SERPINA3 KIT CNTN1 BMPER NME2 0.866 CRP 96 KLK3-SERPINA3 IGFBP2 CNTN1 AKR7A2 CRP 0.866 ITIH4 97 KLK3-SERPINA3 BDNF KIT C9 BMPER 0.866 AKR7A2 98 KLK3-SERPINA3 GHR IGFBP4 BMPER AKR7A2 0.866 CRP 99 BDNF KIT IGFBP2 AHSG AKR7A2 0.866 CRP 100 KLK3-SERPINA3 KIT C9 BMPER AKR7A2 0.866 ITIH4

TABLE 26 Panels of 7 Biomarkers Markers Mean CV AUC 1 KLK3-SERPINA3 KIT GHR CNTN1 C9 0.875 BMPER AKR7A2 2 KLK3-SERPINA3 KIT IGFBP2 CNTN1 C9 0.875 BMPER AKR7A2 3 KLK3-SERPINA3 KIT CNTN1 C9 BMP1 0.875 BMPER AKR7A2 4 KLK3-SERPINA3 KIT IGFBP2 CNTN1 BMPER 0.874 AKR7A2 CRP 5 KLK3-SERPINA3 KIT CNTN1 BMP1 BMPER 0.873 AKR7A2 ITIH4 6 KLK3-SERPINA3 IGFBP4 CNTN1 C9 BMPER 0.873 AKR7A2 ITIH4 7 KLK3-SERPINA3 BDNF KIT IGFBP2 CNTN1 0.873 AKR7A2 CRP 8 KIT GHR CNTN1 C9 BMPER 0.873 AKR7A2 CRP 9 KLK3-SERPINA3 KIT IGFBP4 CNTN1 C9 0.873 BMPER AKR7A2 10 KLK3-SERPINA3 KIT IGFBP4 C9 BMPER 0.873 AKR7A2 ITIH4 11 KLK3-SERPINA3 BDNF KIT CNTN1 C9 0.872 BMPER AKR7A2 12 KLK3-SERPINA3 KIT IGFBP2 CNTN1 BMP1 0.872 AKR7A2 CRP 13 KLK3-SERPINA3 KIT GHR CNTN1 BMPER 0.872 AKR7A2 CRP 14 KLK3-SERPINA3 IGFBP4 CNTN1 BMP1 BMPER 0.872 AKR7A2 ITIH4 15 KIT GHR CNTN1 BMP1 BMPER 0.872 AKR7A2 CRP 16 KLK3-SERPINA3 IGFBP2 CNTN1 BMPER AKR7A2 0.872 CRP ITIH4 17 KLK3-SERPINA3 KIT GHR C9 BMPER 0.872 AKR7A2 CRP 18 KLK3-SERPINA3 KIT GHR IGFBP4 C9 0.872 BMPER AKR7A2 19 KLK3-SERPINA3 KIT CNTN1 BMP1 BMPER 0.872 AKR7A2 CRP 20 KLK3-SERPINA3 KIT GHR CNTN1 C9 0.872 BMPER NME2 21 KLK3-SERPINA3 BDNF KIT CNTN1 C9 0.872 AKR7A2 CRP 22 KLK3-SERPINA3 KIT IGFBP4 CNTN1 BMP1 0.872 NME2 ITIH4 23 KLK3-SERPINA3 KIT IGFBP2 CNTN1 BMPER 0.872 AKR7A2 ITIH4 24 KLK3-SERPINA3 IGFBP2 IGFBP4 CNTN1 BMPER 0.872 AKR7A2 ITIH4 25 KLK3-SERPINA3 IGFBP4 CNTN1 BMP1 AKR7A2 0.872 CRP ITIH4 26 KIT GHR C9 BMP1 BMPER 0.872 AKR7A2 CRP 27 KLK3-SERPINA3 IGFBP4 CNTN1 C9 BMP1 0.872 BMPER AKR7A2 28 KLK3-SERPINA3 IGFBP2 GHR CNTN1 BMPER 0.872 AKR7A2 CRP 29 KIT GHR CNTN1 C9 BMP1 0.872 BMPER AKR7A2 30 KLK3-SERPINA3 KIT CNTN1 C9 AHSG 0.872 BMPER AKR7A2 31 KLK3-SERPINA3 IGFBP2 CNTN1 DDC BMPER 0.872 AKR7A2 ITIH4 32 KLK3-SERPINA3 KIT GHR IGFBP4 BMPER 0.872 AKR7A2 CRP 33 KLK3-SERPINA3 KIT GHR CNTN1 BMP1 0.872 BMPER AKR7A2 34 KLK3-SERPINA3 KIT IGFBP2 CNTN1 BMP1 0.872 BMPER AKR7A2 35 KLK3-SERPINA3 KIT GHR BMP1 BMPER 0.871 AKR7A2 CRP 36 KLK3-SERPINA3 GHR IGFBP4 CNTN1 C9 0.871 BMPER AKR7A2 37 BDNF KIT IGFBP2 CNTN1 C9 0.871 AKR7A2 CRP 38 BDNF KIT GHR C9 BMPER 0.871 AKR7A2 CRP 39 KIT IGFBP2 CNTN1 C9 BMPER 0.871 AKR7A2 CRP 40 KLK3-SERPINA3 KIT IGFBP2 CNTN1 BMPER 0.871 NME2 CRP 41 KLK3-SERPINA3 KIT IGFBP4 CNTN1 C9 0.871 BMP1 AKR7A2 42 KIT GHR C9 AHSG BMPER 0.871 AKR7A2 CRP 43 KLK3-SERPINA3 IGFBP2 CNTN1 C9 BMPER 0.871 AKR7A2 ITIH4 44 KLK3-SERPINA3 KIT GHR CNTN1 BMP1 0.871 AKR7A2 CRP 45 KLK3-SERPINA3 KIT IGFBP4 CNTN1 BMP1 0.871 AKR7A2 ITIH4 46 KLK3-SERPINA3 IGFBP2 IGFBP4 CNTN1 BMPER 0.871 AKR7A2 CRP 47 KLK3-SERPINA3 IGFBP2 CNTN1 C9 BMPER 0.871 AKR7A2 CRP 48 KLK3-SERPINA3 GHR IGFBP4 BMPER AKR7A2 0.871 CRP ITIH4 49 KLK3-SERPINA3 KIT GHR CNTN1 BMPER 0.871 AKR7A2 ITIH4 50 KLK3-SERPINA3 IGFBP2 CNTN1 BMP1 AKR7A2 0.871 CRP ITIH4 51 KLK3-SERPINA3 IGFBP2 IGFBP4 BMPER AKR7A2 0.871 CRP ITIH4 52 KLK3-SERPINA3 KIT IGFBP4 CNTN1 BMPER 0.871 AKR7A2 ITIH4 53 KLK3-SERPINA3 KIT CNTN1 C9 BMPER 0.871 AKR7A2 ITIH4 54 KLK3-SERPINA3 IGFBP2 CNTN1 BMP1 BMPER 0.871 AKR7A2 CRP 55 KLK3-SERPINA3 KIT IGFBP2 CNTN1 BMP1 0.871 NME2 CRP 56 KLK3-SERPINA3 KIT IGFBP4 CNTN1 C9 0.871 AKR7A2 ITIH4 57 KLK3-SERPINA3 KIT EGFR CNTN1 C9 0.870 BMPER AKR7A2 58 KLK3-SERPINA3 KIT IGFBP4 C9 BMP1 0.870 BMPER AKR7A2 59 KLK3-SERPINA3 IGFBP2 CNTN1 BMP1 BMPER 0.870 AKR7A2 ITIH4 60 KLK3-SERPINA3 GHR IGFBP4 CNTN1 BMPER 0.870 AKR7A2 ITIH4 61 KLK3-SERPINA3 BDNF KIT CNTN1 C9 0.870 BMP1 AKR7A2 62 KIT IGFBP2 CNTN1 BMP1 BMPER 0.870 AKR7A2 CRP 63 KLK3-SERPINA3 BDNF KIT CNTN1 BMP1 0.870 AKR7A2 CRP 64 KLK3-SERPINA3 GHR CNTN1 C9 BMPER 0.870 AKR7A2 CRP 65 KLK3-SERPINA3 IGFBP4 CNTN1 BMP1 BMPER 0.870 NME2 ITIH4 66 KLK3-SERPINA3 KIT IGFBP2 C9 BMPER 0.870 AKR7A2 CRP 67 KLK3-SERPINA3 BDNF KIT IGFBP2 CNTN1 0.870 C9 AKR7A2 68 KLK3-SERPINA3 KIT IGFBP4 BMP1 AKR7A2 0.870 CRP ITIH4 69 KIT GHR CNTN1 C9 BMP1 0.870 AKR7A2 CRP 70 KLK3-SERPINA3 KIT CNTN1 C9 BMP1 0.870 DDC AKR7A2 71 KLK3-SERPINA3 KIT CNTN1 C9 BMPER 0.870 AKR7A2 CRP 72 KLK3-SERPINA3 KIT GHR IGFBP4 C9 0.870 AKR7A2 CRP 73 KLK3-SERPINA3 KIT GHR IGFBP4 BMP1 0.870 AKR7A2 CRP 74 KLK3-SERPINA3 BDNF KIT C9 BMPER 0.870 AKR7A2 CRP 75 KLK3-SERPINA3 KIT CNTN1 BMP1 BMPER 0.870 NME2 CRP 76 KLK3-SERPINA3 IGFBP2 IGFBP4 CNTN1 AKR7A2 0.870 CRP ITIH4 77 KLK3-SERPINA3 GHR CNTN1 BMP1 BMPER 0.870 AKR7A2 CRP 78 KLK3-SERPINA3 KIT CNTN1 C9 BMP1 0.870 BMPER NME2 79 KLK3-SERPINA3 KIT IGFBP2 GHR BMPER 0.870 AKR7A2 CRP 80 KLK3-SERPINA3 KIT EGFR CNTN1 BMP1 0.870 AKR7A2 CRP 81 KLK3-SERPINA3 KIT IGFBP4 CNTN1 BMP1 0.870 AKR7A2 CRP 82 KIT EGFR GHR C9 BMPER 0.870 AKR7A2 CRP 83 KLK3-SERPINA3 KIT GHR C9 AHSG 0.870 BMPER AKR7A2 84 KLK3-SERPINA3 BDNF IGFBP2 CNTN1 C9 0.870 AKR7A2 CRP 85 KIT IGFBP2 GHR C9 BMPER 0.870 AKR7A2 CRP 86 KLK3-SERPINA3 KIT IGFBP4 BMPER AKR7A2 0.870 CRP ITIH4 87 KLK3-SERPINA3 KIT GHR C9 BMP1 0.870 BMPER AKR7A2 88 KLK3-SERPINA3 KIT CNTN1 C9 BMP1 0.870 AKR7A2 CRP 89 KLK3-SERPINA3 KIT EGFR CNTN1 C9 0.870 BMP1 AKR7A2 90 KLK3-SERPINA3 KIT EGFR C9 BMPER 0.870 AKR7A2 ITIH4 91 KLK3-SERPINA3 KIT IGFBP2 CNTN1 DDC 0.870 BMPER AKR7A2 92 BDNF KIT IGFBP2 C9 BMPER 0.870 AKR7A2 CRP 93 KLK3-SERPINA3 IGFBP2 IGFBP4 CNTN1 C9 0.870 BMPER AKR7A2 94 KLK3-SERPINA3 KIT CNTN1 C9 CA6 0.870 BMPER AKR7A2 95 KLK3-SERPINA3 KIT GHR IGFBP4 AKR7A2 0.870 CRP ITIH4 96 KLK3-SERPINA3 KIT GHR CNTN1 C9 0.870 AKR7A2 CRP 97 KLK3-SERPINA3 IGFBP2 CNTN1 C9 DDC 0.870 BMPER AKR7A2 98 KLK3-SERPINA3 KIT CNTN1 C9 DDC 0.870 BMPER AKR7A2 99 KLK3-SERPINA3 IGFBP4 CNTN1 C9 BMPER 0.870 NME2 ITIH4 100 KIT CNTN1 C9 BMP1 BMPER 0.870 AKR7A2 CRP

TABLE 27 Panels of 8 Biomarkers Markers Mean CV AUC 1 KLK3-SERPINA3 KIT GHR CNTN1 C9 0.877 BMP1 BMPER AKR7A2 2 KLK3-SERPINA3 KIT IGFBP4 CNTN1 BMP1 0.876 BMPER AKR7A2 ITIH4 3 KLK3-SERPINA3 KIT GHR IGFBP4 BMPER 0.876 AKR7A2 CRP ITIH4 4 KLK3-SERPINA3 KIT GHR IGFBP4 CNTN1 0.876 C9 BMPER AKR7A2 5 KLK3-SERPINA3 KIT GHR CNTN1 C9 0.876 AHSG BMPER AKR7A2 6 KLK3-SERPINA3 KIT GHR CNTN1 BMP1 0.876 BMPER AKR7A2 CRP 7 KLK3-SERPINA3 IGFBP2 IGFBP4 CNTN1 BMPER 0.876 AKR7A2 CRP ITIH4 8 KIT GHR CNTN1 C9 BMP1 0.876 BMPER AKR7A2 CRP 9 KLK3-SERPINA3 KIT IGFBP2 GHR CNTN1 0.876 BMPER AKR7A2 CRP 10 KLK3-SERPINA3 KIT IGFBP2 CNTN1 BMP1 0.876 BMPER AKR7A2 CRP 11 KLK3-SERPINA3 KIT GHR CNTN1 C9 0.875 BMPER AKR7A2 CRP 12 KLK3-SERPINA3 KIT IGFBP4 CNTN1 C9 0.875 BMPER AKR7A2 ITIH4 13 KLK3-SERPINA3 KIT IGFBP4 CNTN1 C9 0.875 BMP1 BMPER AKR7A2 14 KLK3-SERPINA3 KIT IGFBP2 CNTN1 C9 0.875 AHSG BMPER AKR7A2 15 KLK3-SERPINA3 KIT IGFBP2 CNTN1 C9 0.875 BMPER AKR7A2 CRP 16 KLK3-SERPINA3 KIT GHR CNTN1 BMP1 0.875 BMPER AKR7A2 ITIH4 17 KLK3-SERPINA3 KIT IGFBP4 CNTN1 BMP1 0.875 AKR7A2 CRP ITIH4 18 KLK3-SERPINA3 KIT GHR IGFBP4 C9 0.875 BMPER AKR7A2 ITIH4 19 KLK3-SERPINA3 KIT GHR IGFBP4 CNTN1 0.875 BMP1 AKR7A2 CRP 20 KLK3-SERPINA3 KIT CNTN1 C9 BMP1 0.874 AHSG BMPER AKR7A2 21 KLK3-SERPINA3 KIT IGFBP2 GHR CNTN1 0.874 C9 BMPER AKR7A2 22 KLK3-SERPINA3 KIT GHR IGFBP4 C9 0.874 BMPER AKR7A2 CRP 23 KLK3-SERPINA3 KIT IGFBP2 CNTN1 C9 0.874 BMP1 BMPER AKR7A2 24 KLK3-SERPINA3 KIT GHR CNTN1 C9 0.874 CA6 BMPER AKR7A2 25 KLK3-SERPINA3 KIT IGFBP4 BMP1 BMPER 0.874 AKR7A2 CRP ITIH4 26 KLK3-SERPINA3 KIT IGFBP2 CNTN1 BMP1 0.874 BMPER AKR7A2 ITIH4 27 KLK3-SERPINA3 KIT IGFBP4 CNTN1 BMP1 0.874 BMPER NME2 ITIH4 28 KLK3-SERPINA3 KIT GHR CNTN1 BMP1 0.874 BMPER NME2 CRP 29 KLK3-SERPINA3 KIT IGFBP2 CNTN1 BMPER 0.874 AKR7A2 CRP ITIH4 30 KLK3-SERPINA3 KIT GHR CNTN1 C9 0.874 BMP1 AKR7A2 CRP 31 KLK3-SERPINA3 KIT GHR CNTN1 BMPER 0.874 AKR7A2 CRP ITIH4 32 KLK3-SERPINA3 KIT GHR IGFBP4 CNTN1 0.874 BMPER AKR7A2 CRP 33 KLK3-SERPINA3 GHR IGFBP4 CNTN1 BMP1 0.874 AKR7A2 CRP ITIH4 34 KLK3-SERPINA3 KIT IGFBP2 CNTN1 C9 0.874 BMPER AKR7A2 ITIH4 35 KLK3-SERPINA3 KIT GHR IGFBP4 CNTN1 0.874 BMPER AKR7A2 ITIH4 36 KLK3-SERPINA3 IGFBP2 IGFBP4 CNTN1 C9 0.874 BMPER AKR7A2 ITIH4 37 KLK3-SERPINA3 KIT IGFBP4 C9 BMP1 0.874 BMPER AKR7A2 ITIH4 38 KLK3-SERPINA3 KIT GHR CNTN1 C9 0.874 BMPER AKR7A2 ITIH4 39 KIT IGFBP2 GHR CNTN1 C9 0.874 BMPER AKR7A2 CRP 40 KLK3-SERPINA3 KIT GHR IGFBP4 BMP1 0.874 BMPER AKR7A2 CRP 41 KIT GHR IGFBP4 C9 BMPER 0.873 AKR7A2 CRP ITIH4 42 KLK3-SERPINA3 GHR IGFBP4 CNTN1 C9 0.873 BMPER AKR7A2 ITIH4 43 KLK3-SERPINA3 GHR IGFBP4 CNTN1 C9 0.873 BMPER AKR7A2 CRP 44 KLK3-SERPINA3 KIT IGFBP4 CNTN1 BMP1 0.873 BMPER AKR7A2 CRP 45 KLK3-SERPINA3 KIT GHR BMP1 BMPER 0.873 AKR7A2 CRP ITIH4 46 KLK3-SERPINA3 KIT IGFBP4 C9 AHSG 0.873 BMPER AKR7A2 ITIH4 47 KLK3-SERPINA3 KIT IGFBP4 CNTN1 C9 0.873 BMP1 AKR7A2 ITIH4 48 KLK3-SERPINA3 GHR IGFBP4 CNTN1 BMP1 0.873 BMPER AKR7A2 CRP 49 BDNF KIT GHR CNTN1 C9 0.873 BMPER AKR7A2 CRP 50 KLK3-SERPINA3 KIT IGFBP4 C9 DDC 0.873 BMPER AKR7A2 ITIH4 51 KLK3-SERPINA3 KIT GHR IGFBP4 BMP1 0.873 AKR7A2 CRP ITIH4 52 KLK3-SERPINA3 KIT IGFBP2 CNTN1 DDC 0.873 BMPER AKR7A2 ITIH4 53 KLK3-SERPINA3 KIT CNTN1 BMP1 DDC 0.873 BMPER AKR7A2 ITIH4 54 KLK3-SERPINA3 BDNF KIT CNTN1 C9 0.873 BMPER AKR7A2 CRP 55 KLK3-SERPINA3 BDNF KIT IGFBP2 CNTN1 0.873 BMPER AKR7A2 CRP 56 KIT GHR CNTN1 C9 FN1 0.873 BMPER AKR7A2 CRP 57 KLK3-SERPINA3 KIT IGFBP2 IGFBP4 BMPER 0.873 AKR7A2 CRP ITIH4 58 KLK3-SERPINA3 GHR IGFBP4 CNTN1 BMPER 0.873 AKR7A2 CRP ITIH4 59 KLK3-SERPINA3 IGFBP4 CNTN1 C9 AHSG 0.873 BMPER AKR7A2 ITIH4 60 KLK3-SERPINA3 KIT IGFBP4 CNTN1 BMP1 0.873 NME2 CRP ITIH4 61 KLK3-SERPINA3 KIT GHR C9 AHSG 0.873 BMPER AKR7A2 CRP 62 KLK3-SERPINA3 BDNF KIT IGFBP2 CNTN1 0.873 BMP1 AKR7A2 CRP 63 KLK3-SERPINA3 KIT IGFBP2 CNTN1 C9 0.873 DDC BMPER AKR7A2 64 KLK3-SERPINA3 IGFBP2 CNTN1 BMP1 BMPER 0.873 AKR7A2 CRP ITIH4 65 KLK3-SERPINA3 KIT GHR CNTN1 C9 0.873 DDC BMPER AKR7A2 66 KIT GHR IGFBP4 BMP1 BMPER 0.873 AKR7A2 CRP ITIH4 67 KLK3-SERPINA3 BDNF KIT IGFBP2 CNTN1 0.873 AKR7A2 CRP ITIH4 68 KLK3-SERPINA3 KIT IGFBP2 IGFBP4 CNTN1 0.873 C9 BMPER AKR7A2 69 KLK3-SERPINA3 BDNF KIT IGFBP2 CNTN1 0.873 C9 AKR7A2 CRP 70 KLK3-SERPINA3 KIT IGFBP2 IGFBP4 CNTN1 0.873 BMPER AKR7A2 ITIH4 71 KLK3-SERPINA3 KIT IGFBP4 CNTN1 C9 0.873 AHSG BMPER AKR7A2 72 KLK3-SERPINA3 KIT GHR C9 BMP1 0.873 BMPER AKR7A2 CRP 73 KLK3-SERPINA3 IGFBP2 IGFBP4 CNTN1 BMP1 0.873 AKR7A2 CRP ITIH4 74 KLK3-SERPINA3 KIT GHR IGFBP4 CNTN1 0.873 BMP1 NME2 CRP 75 KLK3-SERPINA3 KIT GHR IGFBP4 BMPER 0.873 NME2 CRP ITIH4 76 KLK3-SERPINA3 KIT IGFBP2 CNTN1 BMP1 0.873 DDC AKR7A2 CRP 77 KLK3-SERPINA3 KIT CNTN1 BMP1 BMPER 0.873 AKR7A2 CRP ITIH4 78 BDNF KIT IGFBP2 CNTN1 C9 0.873 BMPER AKR7A2 CRP 79 KLK3-SERPINA3 KIT GHR CNTN1 CA6 0.873 BMPER AKR7A2 CRP 80 KLK3-SERPINA3 IGFBP4 CNTN1 C9 BMP1 0.873 BMPER AKR7A2 ITIH4 81 KLK3-SERPINA3 KIT EGFR CNTN1 BMP1 0.873 AKR7A2 CRP ITIH4 82 KLK3-SERPINA3 KIT IGFBP2 CNTN1 C9 0.872 BMP1 AKR7A2 CRP 83 KLK3-SERPINA3 KIT IGFBP2 CNTN1 BMP1 0.872 AKR7A2 CRP ITIH4 84 KLK3-SERPINA3 KIT CNTN1 C9 BMP1 0.872 BMPER AKR7A2 ITIH4 85 KLK3-SERPINA3 KIT GHR IGFBP4 CNTN1 0.872 AKR7A2 CRP ITIH4 86 KLK3-SERPINA3 KIT CNTN1 C9 BMP1 0.872 BMPER AKR7A2 CRP 87 KLK3-SERPINA3 IGFBP4 CNTN1 BMP1 BMPER 0.872 AKR7A2 CRP ITIH4 88 KLK3-SERPINA3 KIT IGFBP2 EGFR CNTN1 0.872 C9 BMPER AKR7A2 89 KLK3-SERPINA3 KIT IGFBP2 CNTN1 AHSG 0.872 BMPER AKR7A2 CRP 90 KLK3-SERPINA3 KIT IGFBP2 GHR C9 0.872 BMPER AKR7A2 CRP 91 KLK3-SERPINA3 KIT GHR IGFBP4 C9 0.872 AKR7A2 CRP ITIH4 92 KLK3-SERPINA3 KIT GHR IGFBP4 C9 0.872 AHSG BMPER AKR7A2 93 KLK3-SERPINA3 KIT GHR IGFBP4 C9 0.872 BMP1 BMPER AKR7A2 94 KLK3-SERPINA3 BDNF KIT IGFBP2 CNTN1 0.872 C9 BMPER AKR7A2 95 KIT GHR CNTN1 C9 AHSG 0.872 BMPER AKR7A2 CRP 96 KLK3-SERPINA3 KIT GHR CNTN1 AHSG 0.872 BMPER AKR7A2 CRP 97 KIT IGFBP2 GHR CNTN1 BMP1 0.872 BMPER AKR7A2 CRP 98 KLK3-SERPINA3 KIT GHR CNTN1 CA6 0.872 BMPER AKR7A2 ITIH4 99 KLK3-SERPINA3 KIT GHR CNTN1 C9 0.872 FN1 BMPER AKR7A2 100 KIT GHR CNTN1 C9 BMP1 0.872 AHSG BMPER AKR7A2

TABLE 28 Panels of 9 Biomarkers Markers Mean CV AUC 1 KLK3-SERPINA3 KIT GHR IGFBP4 BMP1 0.878 BMPER AKR7A2 CRP ITIH4 2 KLK3-SERPINA3 KIT GHR IGFBP4 CNTN1 0.878 BMP1 AKR7A2 CRP ITIH4 3 KLK3-SERPINA3 KIT GHR IGFBP4 CNTN1 0.878 BMPER AKR7A2 CRP ITIH4 4 KLK3-SERPINA3 KIT GHR IGFBP4 CNTN1 0.878 BMP1 BMPER AKR7A2 ITIH4 5 KLK3-SERPINA3 KIT GHR CNTN1 C9 0.877 BMP1 BMPER AKR7A2 CRP 6 KLK3-SERPINA3 KIT IGFBP4 CNTN1 C9 0.877 BMP1 BMPER AKR7A2 ITIH4 7 KLK3-SERPINA3 KIT GHR CNTN1 C9 0.877 BMP1 AHSG BMPER AKR7A2 8 KLK3-SERPINA3 KIT GHR IGFBP4 CNTN1 0.877 BMP1 BMPER AKR7A2 CRP 9 KLK3-SERPINA3 KIT GHR IGFBP4 CNTN1 0.877 C9 BMP1 BMPER AKR7A2 10 KLK3-SERPINA3 KIT GHR IGFBP4 C9 0.877 BMPER AKR7A2 CRP ITIH4 11 KLK3-SERPINA3 KIT GHR IGFBP4 CNTN1 0.877 C9 BMPER AKR7A2 ITIH4 12 KLK3-SERPINA3 KIT IGFBP2 IGFBP4 CNTN1 0.877 BMPER AKR7A2 CRP ITIH4 13 KLK3-SERPINA3 KIT GHR IGFBP4 CNTN1 0.877 C9 BMPER AKR7A2 CRP 14 KLK3-SERPINA3 KIT IGFBP2 GHR CNTN1 0.876 BMP1 BMPER AKR7A2 CRP 15 KLK3-SERPINA3 KIT GHR CNTN1 BMP1 0.876 BMPER AKR7A2 CRP ITIH4 16 KLK3-SERPINA3 KIT GHR IGFBP4 CNTN1 0.876 C9 BMP1 AKR7A2 CRP 17 KLK3-SERPINA3 KIT GHR IGFBP4 CNTN1 0.876 C9 AHSG BMPER AKR7A2 18 KLK3-SERPINA3 KIT IGFBP2 GHR CNTN1 0.876 C9 BMPER AKR7A2 CRP 19 KLK3-SERPINA3 KIT GHR CNTN1 C9 0.876 AHSG BMPER AKR7A2 CRP 20 KLK3-SERPINA3 KIT IGFBP2 CNTN1 BMP1 0.876 BMPER AKR7A2 CRP ITIH4 21 KLK3-SERPINA3 KIT IGFBP2 GHR CNTN1 0.876 BMPER AKR7A2 CRP ITIH4 22 KLK3-SERPINA3 GHR IGFBP4 CNTN1 BMP1 0.876 BMPER AKR7A2 CRP ITIH4 23 KLK3-SERPINA3 KIT GHR IGFBP4 CNTN1 0.876 CA6 BMPER AKR7A2 ITIH4 24 KLK3-SERPINA3 IGFBP2 IGFBP4 CNTN1 BMP1 0.876 BMPER AKR7A2 CRP ITIH4 25 KLK3-SERPINA3 KIT IGFBP4 CNTN1 BMP1 0.876 BMPER AKR7A2 CRP ITIH4 26 KLK3-SERPINA3 KIT IGFBP4 CNTN1 C9 0.876 BMP1 AHSG BMPER AKR7A2 27 KLK3-SERPINA3 KIT IGFBP2 GHR CNTN1 0.876 AHSG BMPER AKR7A2 CRP 28 KLK3-SERPINA3 IGFBP2 GHR IGFBP4 CNTN1 0.876 BMPER AKR7A2 CRP ITIH4 29 KLK3-SERPINA3 KIT IGFBP4 CNTN1 C9 0.875 AHSG BMPER AKR7A2 ITIH4 30 KLK3-SERPINA3 KIT GHR CNTN1 BMP1 0.875 AHSG BMPER AKR7A2 CRP 31 KLK3-SERPINA3 KIT IGFBP2 IGFBP4 CNTN1 0.875 BMP1 AKR7A2 CRP ITIH4 32 KLK3-SERPINA3 KIT IGFBP2 IGFBP4 CNTN1 0.875 C9 BMPER AKR7A2 ITIH4 33 KLK3-SERPINA3 KIT GHR IGFBP4 CNTN1 0.875 C9 AKR7A2 CRP ITIH4 34 KLK3-SERPINA3 KIT GHR IGFBP4 CNTN1 0.875 BMP1 BMPER NME2 CRP 35 KLK3-SERPINA3 KIT GHR IGFBP4 CA6 0.875 BMPER AKR7A2 CRP ITIH4 36 KLK3-SERPINA3 KIT GHR IGFBP4 CNTN1 0.875 C9 CA6 BMPER AKR7A2 37 KLK3-SERPINA3 KIT IGFBP2 GHR IGFBP4 0.875 BMPER AKR7A2 CRP ITIH4 38 KLK3-SERPINA3 KIT GHR IGFBP4 C9 0.875 AHSG BMPER AKR7A2 ITIH4 39 KLK3-SERPINA3 KIT GHR CNTN1 C9 0.875 BMP1 BMPER AKR7A2 ITIH4 40 KLK3-SERPINA3 KIT GHR CNTN1 C9 0.875 CA6 BMPER AKR7A2 CRP 41 KLK3-SERPINA3 KIT IGFBP4 CNTN1 BMP1 0.875 BMPER NME2 CRP ITIH4 42 KLK3-SERPINA3 KIT IGFBP2 IGFBP4 CNTN1 0.875 BMP1 BMPER AKR7A2 ITIH4 43 KLK3-SERPINA3 KIT IGFBP4 CNTN1 BMP1 0.875 AHSG BMPER AKR7A2 ITIH4 44 KLK3-SERPINA3 KIT IGFBP2 IGFBP4 CNTN1 0.875 BMP1 BMPER AKR7A2 CRP 45 KLK3-SERPINA3 KIT GHR IGFBP4 C9 0.875 BMP1 AKR7A2 CRP ITIH4 46 KLK3-SERPINA3 KIT GHR IGFBP4 AHSG 0.874 BMPER AKR7A2 CRP ITIH4 47 KLK3-SERPINA3 KIT IGFBP4 CNTN1 BMP1 0.874 DDC BMPER AKR7A2 ITIH4 48 KLK3-SERPINA3 KIT IGFBP2 CNTN1 BMP1 0.874 DDC BMPER AKR7A2 ITIH4 49 KLK3-SERPINA3 KIT IGFBP2 IGFBP4 C9 0.874 BMPER AKR7A2 CRP ITIH4 50 KLK3-SERPINA3 KIT EGFR GHR CNTN1 0.874 C9 AHSG BMPER AKR7A2 51 KLK3-SERPINA3 KIT IGFBP2 GHR IGFBP4 0.874 CNTN1 BMPER AKR7A2 CRP 52 KLK3-SERPINA3 KIT GHR IGFBP4 C9 0.874 BMP1 BMPER AKR7A2 ITIH4 53 KLK3-SERPINA3 KIT GHR IGFBP4 CNTN1 0.874 C9 SERPINA1 BMPER AKR7A2 54 KLK3-SERPINA3 IGFBP2 IGFBP4 CNTN1 AHSG 0.874 BMPER AKR7A2 CRP ITIH4 55 KLK3-SERPINA3 KIT IGFBP2 CNTN1 C9 0.874 DDC BMPER AKR7A2 ITIH4 56 KLK3-SERPINA3 KIT IGFBP2 GHR CNTN1 0.874 C9 AHSG BMPER AKR7A2 57 KLK3-SERPINA3 KIT IGFBP2 CNTN1 C9 0.874 BMP1 BMPER AKR7A2 CRP 58 KLK3-SERPINA3 KIT IGFBP2 CNTN1 C9 0.874 AHSG BMPER AKR7A2 CRP 59 KLK3-SERPINA3 KIT GHR CNTN1 BMP1 0.874 FN1 BMPER AKR7A2 CRP 60 KLK3-SERPINA3 GHR IGFBP4 CNTN1 C9 0.874 BMPER AKR7A2 CRP ITIH4 61 KLK3-SERPINA3 KIT IGFBP2 CNTN1 C9 0.874 BMP1 AHSG BMPER AKR7A2 62 KLK3-SERPINA3 KIT IGFBP2 GHR IGFBP4 0.874 CNTN1 C9 BMPER AKR7A2 63 KIT GHR IGFBP4 CNTN1 C9 0.874 BMPER AKR7A2 CRP ITIH4 64 KLK3-SERPINA3 KIT GHR IGFBP4 CNTN1 0.874 CA6 BMPER AKR7A2 CRP 65 KLK3-SERPINA3 KIT GHR IGFBP4 CNTN1 0.874 CA6 AKR7A2 CRP ITIH4 66 KLK3-SERPINA3 KIT GHR CNTN1 C9 0.874 BMP1 FN1 BMPER AKR7A2 67 KLK3-SERPINA3 KIT GHR IGFBP4 FN1 0.874 BMPER AKR7A2 CRP ITIH4 68 KIT GHR IGFBP4 C9 BMP1 0.874 BMPER AKR7A2 CRP ITIH4 69 KLK3-SERPINA3 KIT GHR CNTN1 CA6 0.874 BMPER AKR7A2 CRP ITIH4 70 KLK3-SERPINA3 KIT GHR IGFBP4 CNTN1 0.874 BMP1 NME2 CRP ITIH4 71 KLK3-SERPINA3 KIT IGFBP2 IGFBP4 BMP1 0.874 BMPER AKR7A2 CRP ITIH4 72 KLK3-SERPINA3 BDNF KIT GHR CNTN1 0.874 C9 BMPER AKR7A2 CRP 73 KLK3-SERPINA3 KIT GHR IGFBP4 C9 0.874 AHSG BMPER AKR7A2 CRP 74 KLK3-SERPINA3 KIT IGFBP4 CNTN1 C9 0.874 BMP1 AKR7A2 CRP ITIH4 75 KLK3-SERPINA3 KIT GHR IGFBP4 C9 0.874 CA6 BMPER AKR7A2 ITIH4 76 KLK3-SERPINA3 KIT GHR CNTN1 C9 0.874 CA6 BMPER AKR7A2 ITIH4 77 KIT IGFBP2 GHR CNTN1 C9 0.874 BMP1 BMPER AKR7A2 CRP 78 KLK3-SERPINA3 BDNF KIT IGFBP2 CNTN1 0.874 C9 BMPER AKR7A2 CRP 79 KLK3-SERPINA3 KIT IGFBP2 EGFR CNTN1 0.874 C9 AHSG BMPER AKR7A2 80 KLK3-SERPINA3 KIT GHR IGFBP4 CNTN1 0.874 BMPER NME2 CRP ITIH4 81 KLK3-SERPINA3 KIT EGFR CNTN1 C9 0.874 BMP1 AHSG BMPER AKR7A2 82 KLK3-SERPINA3 GHR IGFBP4 CNTN1 CA6 0.874 BMPER AKR7A2 CRP ITIH4 83 KLK3-SERPINA3 KIT GHR IGFBP4 BMP1 0.874 BMPER NME2 CRP ITIH4 84 KLK3-SERPINA3 KIT IGFBP4 CNTN1 BMP1 0.874 AKR7A2 NME2 CRP ITIH4 85 KLK3-SERPINA3 KIT IGFBP4 CNTN1 C9 0.874 DDC BMPER AKR7A2 ITIH4 86 KIT IGFBP2 GHR CNTN1 C9 0.874 AHSG BMPER AKR7A2 CRP 87 KLK3-SERPINA3 KIT GHR CNTN1 C9 0.874 BMPER AKR7A2 CRP ITIH4 88 KLK3-SERPINA3 KIT GHR CNTN1 C9 0.874 BMP1 DDC BMPER AKR7A2 89 KLK3-SERPINA3 KIT GHR C9 BMP1 0.874 AHSG BMPER AKR7A2 CRP 90 KLK3-SERPINA3 KIT GHR CNTN1 BMP1 0.874 CA6 BMPER AKR7A2 CRP 91 KLK3-SERPINA3 KIT IGFBP2 CNTN1 BMP1 0.874 DDC BMPER AKR7A2 CRP 92 KIT GHR CNTN1 C9 BMP1 0.874 AHSG BMPER AKR7A2 CRP 93 KLK3-SERPINA3 KIT IGFBP2 CNTN1 BMP1 0.874 AHSG BMPER AKR7A2 CRP 94 KLK3-SERPINA3 KIT IGFBP2 CNTN1 BMP1 0.874 DDC AKR7A2 CRP ITIH4 95 KLK3-SERPINA3 IGFBP2 IGFBP4 CNTN1 DDC 0.874 BMPER AKR7A2 CRP ITIH4 96 KLK3-SERPINA3 GHR IGFBP4 CNTN1 AHSG 0.874 BMPER AKR7A2 CRP ITIH4 97 KLK3-SERPINA3 KIT IGFBP2 GHR CNTN1 0.874 CA6 BMPER AKR7A2 CRP 98 KLK3-SERPINA3 KIT GHR IGFBP4 CNTN1 0.874 BMP1 SERPINA1 BMPER AKR7A2 99 KIT GHR IGFBP4 CNTN1 BMP1 0.874 BMPER AKR7A2 CRP ITIH4 100 KLK3-SERPINA3 KIT GHR CNTN1 C9 0.874 BMP1 AHSG AKR7A2 CRP

TABLE 29 Panels of 10 Biomarkers Markers Mean CV AUC 1 KLK3-SERPINA3 KIT IGFBP2 GHR IGFBP4 0.880 CNTN1 BMPER AKR7A2 CRP ITIH4 2 KLK3-SERPINA3 KIT GHR IGFBP4 CNTN1 0.880 BMP1 BMPER AKR7A2 CRP ITIH4 3 KLK3-SERPINA3 KIT GHR IGFBP4 CNTN1 0.878 CA6 BMPER AKR7A2 CRP ITIH4 4 KLK3-SERPINA3 KIT IGFBP2 IGFBP4 CNTN1 0.878 BMP1 BMPER AKR7A2 CRP ITIH4 5 KLK3-SERPINA3 KIT IGFBP4 CNTN1 C9 0.878 BMPER AKR7A2 NME2 CRP ITIH4 6 KLK3-SERPINA3 KIT GHR IGFBP4 CNTN1 0.878 C9 BMP1 BMPER AKR7A2 ITIH4 7 KLK3-SERPINA3 KIT GHR IGFBP4 C9 0.878 BMP1 BMPER AKR7A2 CRP ITIH4 8 KLK3-SERPINA3 KIT GHR IGFBP4 CNTN1 0.877 C9 BMPER AKR7A2 CRP ITIH4 9 KLK3-SERPINA3 KIT GHR IGFBP4 CNTN1 0.877 BMP1 AHSG AKR7A2 CRP ITIH4 10 KLK3-SERPINA3 KIT GHR IGFBP4 CNTN1 0.877 BMP1 BMPER NME2 CRP ITIH4 11 KLK3-SERPINA3 KIT IGFBP2 GHR CNTN1 0.877 C9 AHSG BMPER AKR7A2 CRP 12 KLK3-SERPINA3 KIT GHR IGFBP4 CNTN1 0.877 C9 CA6 BMPER AKR7A2 ITIH4 13 KLK3-SERPINA3 KIT IGFBP2 IGFBP4 CNTN1 0.877 AHSG BMPER AKR7A2 CRP ITIH4 14 KLK3-SERPINA3 KIT GHR IGFBP4 CNTN1 0.877 BMP1 CA6 BMPER AKR7A2 ITIH4 15 KLK3-SERPINA3 KIT GHR IGFBP4 CNTN1 0.877 C9 BMP1 BMPER AKR7A2 CRP 16 KLK3-SERPINA3 KIT GHR IGFBP4 CNTN1 0.877 BMP1 CA6 AKR7A2 CRP ITIH4 17 KLK3-SERPINA3 KIT IGFBP4 CNTN1 BMP1 0.877 BMPER AKR7A2 NME2 CRP ITIH4 18 KLK3-SERPINA3 KIT IGFBP4 CNTN1 C9 0.877 BMP1 AHSG BMPER AKR7A2 ITIH4 19 KLK3-SERPINA3 KIT GHR IGFBP4 CNTN1 0.877 C9 BMP1 AHSG BMPER AKR7A2 20 KLK3-SERPINA3 KIT GHR IGFBP4 CNTN1 0.876 AHSG BMPER AKR7A2 CRP ITIH4 21 KLK3-SERPINA3 KIT GHR IGFBP4 C9 0.876 AHSG BMPER AKR7A2 CRP ITIH4 22 KLK3-SERPINA3 KIT GHR CNTN1 C9 0.876 BMP1 AHSG BMPER AKR7A2 CRP 23 KLK3-SERPINA3 KIT GHR IGFBP4 CNTN1 0.876 C9 BMP1 AKR7A2 CRP ITIH4 24 KLK3-SERPINA3 KIT GHR IGFBP4 CNTN1 0.876 C9 AHSG BMPER AKR7A2 ITIH4 25 KLK3-SERPINA3 KIT IGFBP2 GHR CNTN1 0.876 BMP1 AHSG BMPER AKR7A2 CRP 26 KLK3-SERPINA3 KIT GHR IGFBP4 CNTN1 0.876 C9 AHSG BMPER AKR7A2 CRP 27 KLK3-SERPINA3 KIT IGFBP2 GHR CNTN1 0.876 BMP1 BMPER AKR7A2 CRP ITIH4 28 KLK3-SERPINA3 KIT IGFBP4 CNTN1 C9 0.876 BMP1 BMPER AKR7A2 NME2 ITIH4 29 KLK3-SERPINA3 KIT IGFBP2 GHR CNTN1 0.876 CA6 BMPER AKR7A2 CRP ITIH4 30 KLK3-SERPINA3 GHR IGFBP4 CNTN1 BMP1 0.876 AHSG BMPER AKR7A2 CRP ITIH4 31 KLK3-SERPINA3 KIT IGFBP2 GHR IGFBP4 0.876 CNTN1 BMP1 BMPER AKR7A2 CRP 32 KLK3-SERPINA3 KIT IGFBP2 GHR CNTN1 0.876 C9 BMP1 BMPER AKR7A2 CRP 33 KLK3-SERPINA3 KIT GHR IGFBP4 C9 0.876 BMPER AKR7A2 NME2 CRP ITIH4 34 KLK3-SERPINA3 KIT GHR IGFBP4 CNTN1 0.876 C9 CA6 BMPER AKR7A2 CRP 35 KLK3-SERPINA3 KIT GHR CNTN1 C9 0.876 CA6 AHSG BMPER AKR7A2 CRP 36 KLK3-SERPINA3 KIT IGFBP2 CNTN1 BMP1 0.876 AHSG BMPER AKR7A2 CRP ITIH4 37 KLK3-SERPINA3 KIT GHR IGFBP4 CNTN1 0.876 C9 CA6 AHSG BMPER AKR7A2 38 KLK3-SERPINA3 KIT GHR CNTN1 C9 0.876 BMP1 FN1 BMPER AKR7A2 CRP 39 KLK3-SERPINA3 KIT GHR IGFBP4 CNTN1 0.875 BMP1 CA6 BMPER AKR7A2 CRP 40 KLK3-SERPINA3 KIT GHR IGFBP4 CNTN1 0.875 C9 BMP1 AHSG AKR7A2 CRP 41 KLK3-SERPINA3 IGFBP2 GHR IGFBP4 CNTN1 0.875 C9 BMPER AKR7A2 CRP ITIH4 42 KLK3-SERPINA3 KIT GHR IGFBP4 CNTN1 0.875 BMP1 AHSG BMPER AKR7A2 CRP 43 KLK3-SERPINA3 KIT GHR IGFBP4 CNTN1 0.875 C9 DDC BMPER AKR7A2 ITIH4 44 KLK3-SERPINA3 KIT IGFBP2 GHR IGFBP4 0.875 CNTN1 C9 BMPER AKR7A2 CRP 45 KLK3-SERPINA3 KIT IGFBP2 CNTN1 BMP1 0.875 DDC BMPER AKR7A2 CRP ITIH4 46 KLK3-SERPINA3 KIT IGFBP2 GHR CNTN1 0.875 AHSG BMPER AKR7A2 CRP ITIH4 47 KLK3-SERPINA3 KIT IGFBP4 CNTN1 C9 0.875 BMP1 AKR7A2 NME2 CRP ITIH4 48 KLK3-SERPINA3 KIT IGFBP2 IGFBP4 CNTN1 0.875 BMP1 DDC AKR7A2 CRP ITIH4 49 KLK3-SERPINA3 GHR IGFBP4 CNTN1 C9 0.875 AHSG BMPER AKR7A2 CRP ITIH4 50 KLK3-SERPINA3 KIT IGFBP2 GHR IGFBP4 0.875 C9 BMPER AKR7A2 CRP ITIH4 51 KLK3-SERPINA3 KIT GHR CNTN1 C9 0.875 BMPER AKR7A2 NME2 CRP ITIH4 52 KLK3-SERPINA3 KIT IGFBP4 CNTN1 BMP1 0.875 CA6 BMPER AKR7A2 CRP ITIH4 53 KLK3-SERPINA3 KIT GHR IGFBP4 BMP1 0.875 CA6 BMPER AKR7A2 CRP ITIH4 54 KLK3-SERPINA3 KIT IGFBP2 GHR IGFBP4 0.875 CNTN1 C9 BMPER AKR7A2 ITIH4 55 KLK3-SERPINA3 KIT GHR IGFBP4 CNTN1 0.875 BMPER AKR7A2 NME2 CRP ITIH4 56 KLK3-SERPINA3 KIT IGFBP2 GHR CNTN1 0.875 C9 CA6 BMPER AKR7A2 CRP 57 KLK3-SERPINA3 KIT GHR CNTN1 BMP1 0.875 AHSG BMPER AKR7A2 CRP ITIH4 58 KLK3-SERPINA3 KIT IGFBP2 CNTN1 C9 0.875 BMPER AKR7A2 NME2 CRP ITIH4 59 KLK3-SERPINA3 KIT GHR IGFBP4 C9 0.875 FN1 BMPER AKR7A2 CRP ITIH4 60 KLK3-SERPINA3 KIT IGFBP2 IGFBP4 CNTN1 0.875 C9 AHSG BMPER AKR7A2 ITIH4 61 KLK3-SERPINA3 KIT GHR CNTN1 C9 0.875 BMP1 FN1 AHSG BMPER AKR7A2 62 KLK3-SERPINA3 IGFBP2 GHR IGFBP4 CNTN1 0.875 BMP1 BMPER AKR7A2 CRP ITIH4 63 KLK3-SERPINA3 KIT GHR CNTN1 C9 0.875 BMP1 DDC AHSG BMPER AKR7A2 64 KLK3-SERPINA3 KIT GHR IGFBP4 BMP1 0.875 FN1 BMPER AKR7A2 CRP ITIH4 65 KLK3-SERPINA3 KIT GHR IGFBP4 BMP1 0.875 BMPER AKR7A2 NME2 CRP ITIH4 66 KLK3-SERPINA3 KIT IGFBP2 IGFBP4 CNTN1 0.875 DDC BMPER AKR7A2 CRP ITIH4 67 KLK3-SERPINA3 KIT EGFR GHR CNTN1 0.875 BMP1 BMPER AKR7A2 CRP ITIH4 68 KLK3-SERPINA3 KIT GHR IGFBP4 CNTN1 0.875 BMP1 AHSG BMPER AKR7A2 ITIH4 69 KLK3-SERPINA3 KIT GHR IGFBP4 CNTN1 0.875 C9 BMP1 BMPER AKR7A2 NME2 70 KLK3-SERPINA3 KIT GHR IGFBP4 CNTN1 0.875 C9 BMPER AKR7A2 NME2 CRP 71 KLK3-SERPINA3 GHR IGFBP4 CNTN1 BMP1 0.875 CA6 BMPER AKR7A2 CRP ITIH4 72 KLK3-SERPINA3 KIT GHR IGFBP4 CNTN1 0.875 C9 SERPINA1 AHSG BMPER AKR7A2 73 KLK3-SERPINA3 GHR IGFBP4 CNTN1 C9 0.875 BMP1 BMPER AKR7A2 CRP ITIH4 74 KLK3-SERPINA3 KIT GHR IGFBP4 BMP1 0.875 AHSG BMPER AKR7A2 CRP ITIH4 75 KLK3-SERPINA3 KIT GHR IGFBP4 CNTN1 0.875 C9 BMPER AKR7A2 NME2 ITIH4 76 KLK3-SERPINA3 KIT GHR CNTN1 C9 0.875 BMP1 BMPER AKR7A2 NME2 CRP 77 KLK3-SERPINA3 KIT IGFBP2 IGFBP4 CNTN1 0.875 C9 BMPER AKR7A2 CRP ITIH4 78 KLK3-SERPINA3 KIT IGFBP2 GHR CNTN1 0.875 DDC BMPER AKR7A2 CRP ITIH4 79 KLK3-SERPINA3 KIT IGFBP2 IGFBP4 CNTN1 0.875 BMPER AKR7A2 NME2 CRP ITIH4 80 KLK3-SERPINA3 KIT IGFBP2 GHR IGFBP4 0.875 CNTN1 CA6 BMPER AKR7A2 CRP 81 KLK3-SERPINA3 IGFBP2 GHR IGFBP4 CNTN1 0.875 AHSG BMPER AKR7A2 CRP ITIH4 82 KLK3-SERPINA3 KIT GHR IGFBP4 CNTN1 0.875 C9 BMP1 SERPINA1 BMPER AKR7A2 83 KLK3-SERPINA3 KIT IGFBP4 CNTN1 C9 0.875 BMP1 DDC BMPER AKR7A2 ITIH4 84 KLK3-SERPINA3 KIT GHR IGFBP4 C9 0.875 BMP1 AHSG BMPER AKR7A2 CRP 85 KLK3-SERPINA3 KIT IGFBP2 GHR CNTN1 0.875 BMP1 FN1 BMPER AKR7A2 CRP 86 KLK3-SERPINA3 KIT GHR CNTN1 BMP1 0.875 FN1 AHSG BMPER AKR7A2 CRP 87 KLK3-SERPINA3 KIT GHR IGFBP4 CNTN1 0.875 C9 FN1 BMPER AKR7A2 CRP 88 KLK3-SERPINA3 KIT IGFBP2 IGFBP4 CNTN1 0.875 C9 BMP1 BMPER AKR7A2 ITIH4 89 KLK3-SERPINA3 KIT GHR IGFBP4 C9 0.875 CA6 BMPER AKR7A2 CRP ITIH4 90 KLK3-SERPINA3 KIT IGFBP2 IGFBP4 C9 0.875 AHSG BMPER AKR7A2 CRP ITIH4 91 KIT GHR IGFBP4 CNTN1 C9 0.875 BMPER AKR7A2 NME2 CRP ITIH4 92 KLK3-SERPINA3 KIT GHR IGFBP4 C9 0.875 BMP1 AHSG AKR7A2 CRP ITIH4 93 KLK3-SERPINA3 KIT IGFBP2 IGFBP4 CNTN1 0.875 BMP1 AHSG BMPER AKR7A2 CRP 94 KLK3-SERPINA3 KIT GHR IGFBP4 C9 0.875 BMP1 FN1 AKR7A2 CRP ITIH4 95 KLK3-SERPINA3 KIT IGFBP2 IGFBP4 C9 0.875 BMPER AKR7A2 NME2 CRP ITIH4 96 KLK3-SERPINA3 KIT IGFBP4 C9 BMP1 0.875 BMPER AKR7A2 NME2 CRP ITIH4 97 KLK3-SERPINA3 KIT GHR IGFBP4 CNTN1 0.875 DDC BMPER AKR7A2 CRP ITIH4 98 KLK3-SERPINA3 KIT IGFBP2 GHR CNTN1 0.875 C9 FN1 BMPER AKR7A2 CRP 99 KLK3-SERPINA3 KIT IGFBP2 GHR IGFBP4 0.875 BMP1 BMPER AKR7A2 CRP ITIH4 100 KLK3-SERPINA3 KIT GHR CNTN1 BMP1 0.874 DDC BMPER AKR7A2 CRP ITIH4

TABLE 30 Counts of markers in biomarker panels Panel Size Biomarker 3 4 5 6 7 8 9 10 AHSG 118 104 104 117 135 211 284 376 AKR7A2 205 485 676 738 810 859 921 950 BDNF 143 212 185 171 162 125 113 78 BMP1 127 157 214 273 308 404 457 495 BMPER 168 205 346 471 572 673 750 820 C9 197 313 402 466 515 536 543 587 CA6 107 96 88 74 96 120 165 223 CKB-CKM 40 1 0 0 0 0 0 0 CNTN1 137 164 235 420 579 717 763 815 CRP 183 267 407 506 558 588 671 721 DDC 110 93 93 109 129 154 161 197 EGFR 135 162 190 196 193 170 177 179 FGA-FGB- 34 0 0 0 0 0 0 0 FGG FN1 90 46 13 11 18 44 70 103 GHR 107 98 126 181 261 398 513 611 IGFBP2 123 127 176 211 277 320 360 380 IGFBP4 97 112 152 198 265 356 461 570 ITIH4 143 148 214 272 379 455 542 636 KIT 147 201 290 481 626 760 836 881 KLK3- 213 448 592 721 809 851 916 947 SERPINA3 NME2 177 337 365 307 245 198 215 310 SERPINA1 83 91 56 31 25 35 60 104 STX1A 116 133 76 46 38 26 22 17

TABLE 31 Parameters derived from cancer datasets set for naïve Bayes classifiers Renal NSCLC Cell Carc. Mesothelioma Can- Can- Control Cancer Control cer Control cer AKR7A2 Mean 6.65 7.35 6.76 7.16 7.48 7.16 SD 0.51 0.48 0.43 0.25 0.58 0.39 BMPER Mean 7.31 7.06 7.45 7.32 7.33 7.21 SD 0.21 0.25 0.11 0.16 0.11 0.20 CNTN1 Mean 9.15 8.89 9.26 9.15 9.14 8.90 SD 0.21 0.36 0.18 0.11 0.19 0.26 CRP Mean 7.84 9.79 7.73 9.00 8.32 10.59 SD 1.06 1.96 1.09 1.42 1.63 1.39 GHR Mean 7.60 7.45 7.72 7.59 7.80 7.67 SD 0.13 0.17 0.14 0.10 0.14 0.17 IGFBP2 Mean 8.45 8.98 8.51 9.01 8.51 8.92 SD 0.47 0.61 0.42 0.45 0.45 0.45 IGFBP4 Mean 7.89 8.05 8.14 8.27 8.15 8.36 SD 0.15 0.24 0.14 0.16 0.20 0.22 ITIH4 Mean 10.18 10.46 10.60 10.74 10.56 10.82 SD 0.32 0.34 0.12 0.23 0.15 0.20 KIT Mean 9.39 9.18 9.60 9.50 9.39 9.25 SD 0.16 0.20 0.14 0.14 0.16 0.19 KLK3- Mean 8.00 8.51 8.10 8.33 8.09 8.68 SERPINA3 SD 0.16 0.53 0.19 0.33 0.23 0.48

TABLE 32 Calculations derived from training set for naïve Bayes classifier. Biomarker μ_(c) μ_(d) σ_(c) σ_(d) {tilde over (x)} p (c|{tilde over (x)}) p (d|{tilde over (x)}) ln (p(d|{tilde over (x)})/p (c|{tilde over (x)})) BMPER 7.450 7.323 0.108 0.164 7.045 0.003 0.576 5.176 KIT 9.603 9.503 0.139 0.141 9.534 2.546 2.767 0.083 AKR7A2 6.761 7.155 0.432 0.248 6.347 0.583 0.008 −4.309 IGFBP4 8.138 8.268 0.140 0.163 8.336 1.046 2.251 0.767 GHR 7.724 7.595 0.135 0.102 7.756 2.867 1.126 −0.935 ITIH4 10.596 10.738 0.121 0.227 10.600 3.301 1.460 −0.816 IGFBP2 8.514 9.006 0.417 0.448 8.812 0.741 0.811 0.091 KLK3-SERPINA3 8.102 8.327 0.194 0.330 7.909 1.253 0.542 −0.838 CNTN1 9.265 9.149 0.181 0.114 9.410 1.602 0.252 −1.848 CRP 7.733 9.005 1.095 1.422 7.675 0.364 0.181 −0.697 

1. A method for diagnosing that an individual does or does not have non-small cell lung cancer (NSCLC), the method comprising: providing a biomarker panel comprising N of the biomarker proteins listed in Table 1; wherein N is an integer from 2 to 59; and detecting biomarker proteins, in a biological sample from an individual, to give biomarker values that each correspond to one of said N biomarker proteins in the panel, wherein said individual is classified as having or not having lung cancer based on said biomarker values.
 2. The method of claim 1, wherein detecting the biomarker values comprises performing an in vitro assay.
 3. The method of claim 2, wherein said in vitro assay comprises at least one capture reagent corresponding to each of said biomarkers, and further comprising selecting said at least one capture reagent from the group consisting of aptamers, antibodies, and a nucleic acid probe.
 4. The method of claim 3, wherein said at least one capture reagent is an aptamer.
 5. The method of claim 2, wherein the in vitro assay is selected from the group consisting of an immunoassay, an aptamer-based assay, a histological or cytological assay, and an mRNA expression level assay.
 6. The method of claim 1, wherein an individual is classified as having ovarian cancer, or the likelihood of the individual having ovarian cancer is determined, based on a classification score that deviates from on a predetermined threshold.
 7. The method claim 1, wherein the biological sample is lung tissue and wherein the biomarker values derive from a histological or cytological analysis of said lung tissue.
 8. The method of claim 1, wherein the biological sample is selected from the group consisting of whole blood, plasma, and serum.
 9. The method of claim 1, wherein the biological sample is serum.
 10. The method of claim 1, wherein the individual is a human.
 11. The method of claim 1, wherein N=2 to
 15. 12. The method of claim 1, wherein N=2 to
 10. 13. The method of claim 1, wherein N=3 to
 10. 14. The method of claim 1, wherein N=4 to
 10. 15. The method of claim 1, wherein N=5 to
 10. 16. The method of claim 1, wherein the individual is a smoker.
 17. The method of claim 1, wherein the individual has a pulmonary nodule.
 18. The method of claim 1, wherein the biomarkers are selected from Table
 13. 19. A computer-implemented method for indicating a likelihood of NSCLC, the method comprising: retrieving on a computer biomarker information for an individual, wherein the biomarker information comprises biomarker values that each correspond to one of at least N biomarkers selected from Table 1; performing with the computer a classification of each of said biomarker values; and indicating a likelihood that said individual has lung cancer based upon a plurality of classifications, and wherein N=2-59. 20-23. (canceled)
 24. A method for screening an asymptomatic high risk individual for NSCL, the method comprising: providing a biomarker panel comprising N of the biomarker proteins listed in Table 1; wherein N is an integer from 2 to 59; and detecting biomarker proteins, in a biological sample from an individual, to give biomarker values that each correspond to one of said N biomarkers proteins in the panel, wherein said individual is classified as having or not having NSCLC, or the likelihood of the individual having NSCLC is determined, based on said biomarker values. 25-41. (canceled)
 42. A method for diagnosing that an individual does or does not have NSCLC, the method comprising: providing a biomarker panel comprising N of the biomarker proteins listed in Table 1; and detecting, in a biological sample from an individual, biomarker values that each correspond to one of said N biomarker proteins in the panel, wherein the biomarker panel has a AUC value of 0.80 or greater.
 43. (canceled)
 45. A method for diagnosing that an individual does or does not have cancer, the method comprising: providing a biomarker panel comprising N of the biomarker proteins listed in Table 19; wherein N is an integer from 3 to 23; and detecting biomarker proteins, in a biological sample from an individual, to give biomarker values that each correspond to one of said N biomarker proteins in the panel, wherein said individual is classified as having or not having cancer based on said biomarker values. 46-56. (canceled)
 57. A computer-implemented method for indicating a likelihood of cancer, the method comprising: retrieving on a computer biomarker information for an individual, wherein the biomarker information comprises biomarker values that each correspond to one of at least N biomarkers selected from Table 19; performing with the computer a classification of each of said biomarker values; and indicating a likelihood that said individual has cancer based upon a plurality of classifications, and wherein N=3-3. 58-61. (canceled)
 62. The method according to claim 1, wherein said individual is classified as having or not having NSCLC, or the likelihood of the individual having NSCLC is determined, based on said biomarker values and at least one item of additional biomedical information corresponding to said individual.
 63. (canceled)
 64. The method according to claim 62, wherein said at least one item of additional biomedical information is independently selected from the group consisting of: (a) information corresponding to physical descriptors of said individual, (b) information corresponding to the radiologic descriptors of a pulmonary abnormality in said individual, (c) information corresponding to the presence or absence of a pulmonary nodule in said individual, (d) information corresponding to physical descriptors of a pulmonary nodule in said individual, (e) information corresponding to a change in height and/or weight of said individual, (f) information corresponding to the ethnicity of said individual, (g) information corresponding to the gender of said individual, (h) information corresponding the smoking history of said individual, (i) information corresponding to environmental tobacco exposure in said individual, (j) information corresponding to alcohol use history in said individual, (k) information corresponding to occupational history of said individual, (l) information corresponding to family history of lung cancer or other cancer in said individual, (m) information corresponding to the presence or absence in said individual of at least one genetic marker correlating with a higher risk of lung cancer or cancer in said individual or a family member of said individual, (n) information corresponding to clinical symptoms of said individual, (o) information corresponding to other laboratory tests, (p) information corresponding to gene expression values of said individual, and (q) information corresponding to said individual's exposure to known carcinogens.
 65. A classifier comprising the biomarkers of Table
 13. 66. A classifier comprising the biomarkers in Example 5, specifically MMP12, MMP7, KLK3-SERPINA3, CRP, C9, CNDP1, and EGFR. 